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Create core.magics.namespace according to new API.
Fernando Perez -
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1 """Implementation of namespace-related magic functions.
2 """
3 #-----------------------------------------------------------------------------
4 # Copyright (c) 2012 The IPython Development Team.
5 #
6 # Distributed under the terms of the Modified BSD License.
7 #
8 # The full license is in the file COPYING.txt, distributed with this software.
9 #-----------------------------------------------------------------------------
10
11 #-----------------------------------------------------------------------------
12 # Imports
13 #-----------------------------------------------------------------------------
14
15 # Stdlib
16 import gc
17 import re
18 import sys
19
20 # Our own packages
21 from IPython.core import page
22 from IPython.core.error import StdinNotImplementedError
23 from IPython.core.magic import Magics, register_magics, line_magic
24 from IPython.testing.skipdoctest import skip_doctest
25 from IPython.utils.encoding import DEFAULT_ENCODING
26 from IPython.utils.path import get_py_filename
27
28 #-----------------------------------------------------------------------------
29 # Magic implementation classes
30 #-----------------------------------------------------------------------------
31
32 @register_magics
33 class NamespaceMagics(Magics):
34 """Magics to manage various aspects of the user's namespace.
35
36 These include listing variables, introspecting into them, etc.
37 """
38
39 @line_magic
40 def pinfo(self, parameter_s='', namespaces=None):
41 """Provide detailed information about an object.
42
43 '%pinfo object' is just a synonym for object? or ?object."""
44
45 #print 'pinfo par: <%s>' % parameter_s # dbg
46
47
48 # detail_level: 0 -> obj? , 1 -> obj??
49 detail_level = 0
50 # We need to detect if we got called as 'pinfo pinfo foo', which can
51 # happen if the user types 'pinfo foo?' at the cmd line.
52 pinfo,qmark1,oname,qmark2 = \
53 re.match('(pinfo )?(\?*)(.*?)(\??$)',parameter_s).groups()
54 if pinfo or qmark1 or qmark2:
55 detail_level = 1
56 if "*" in oname:
57 self.psearch(oname)
58 else:
59 self.shell._inspect('pinfo', oname, detail_level=detail_level,
60 namespaces=namespaces)
61
62 @line_magic
63 def pinfo2(self, parameter_s='', namespaces=None):
64 """Provide extra detailed information about an object.
65
66 '%pinfo2 object' is just a synonym for object?? or ??object."""
67 self.shell._inspect('pinfo', parameter_s, detail_level=1,
68 namespaces=namespaces)
69
70 @skip_doctest
71 @line_magic
72 def pdef(self, parameter_s='', namespaces=None):
73 """Print the definition header for any callable object.
74
75 If the object is a class, print the constructor information.
76
77 Examples
78 --------
79 ::
80
81 In [3]: %pdef urllib.urlopen
82 urllib.urlopen(url, data=None, proxies=None)
83 """
84 self._inspect('pdef',parameter_s, namespaces)
85
86 @line_magic
87 def pdoc(self, parameter_s='', namespaces=None):
88 """Print the docstring for an object.
89
90 If the given object is a class, it will print both the class and the
91 constructor docstrings."""
92 self._inspect('pdoc',parameter_s, namespaces)
93
94 @line_magic
95 def psource(self, parameter_s='', namespaces=None):
96 """Print (or run through pager) the source code for an object."""
97 self._inspect('psource',parameter_s, namespaces)
98
99 @line_magic
100 def pfile(self, parameter_s=''):
101 """Print (or run through pager) the file where an object is defined.
102
103 The file opens at the line where the object definition begins. IPython
104 will honor the environment variable PAGER if set, and otherwise will
105 do its best to print the file in a convenient form.
106
107 If the given argument is not an object currently defined, IPython will
108 try to interpret it as a filename (automatically adding a .py extension
109 if needed). You can thus use %pfile as a syntax highlighting code
110 viewer."""
111
112 # first interpret argument as an object name
113 out = self._inspect('pfile',parameter_s)
114 # if not, try the input as a filename
115 if out == 'not found':
116 try:
117 filename = get_py_filename(parameter_s)
118 except IOError,msg:
119 print msg
120 return
121 page.page(self.shell.inspector.format(open(filename).read()))
122
123 @line_magic
124 def psearch(self, parameter_s=''):
125 """Search for object in namespaces by wildcard.
126
127 %psearch [options] PATTERN [OBJECT TYPE]
128
129 Note: ? can be used as a synonym for %psearch, at the beginning or at
130 the end: both a*? and ?a* are equivalent to '%psearch a*'. Still, the
131 rest of the command line must be unchanged (options come first), so
132 for example the following forms are equivalent
133
134 %psearch -i a* function
135 -i a* function?
136 ?-i a* function
137
138 Arguments:
139
140 PATTERN
141
142 where PATTERN is a string containing * as a wildcard similar to its
143 use in a shell. The pattern is matched in all namespaces on the
144 search path. By default objects starting with a single _ are not
145 matched, many IPython generated objects have a single
146 underscore. The default is case insensitive matching. Matching is
147 also done on the attributes of objects and not only on the objects
148 in a module.
149
150 [OBJECT TYPE]
151
152 Is the name of a python type from the types module. The name is
153 given in lowercase without the ending type, ex. StringType is
154 written string. By adding a type here only objects matching the
155 given type are matched. Using all here makes the pattern match all
156 types (this is the default).
157
158 Options:
159
160 -a: makes the pattern match even objects whose names start with a
161 single underscore. These names are normally omitted from the
162 search.
163
164 -i/-c: make the pattern case insensitive/sensitive. If neither of
165 these options are given, the default is read from your configuration
166 file, with the option ``InteractiveShell.wildcards_case_sensitive``.
167 If this option is not specified in your configuration file, IPython's
168 internal default is to do a case sensitive search.
169
170 -e/-s NAMESPACE: exclude/search a given namespace. The pattern you
171 specify can be searched in any of the following namespaces:
172 'builtin', 'user', 'user_global','internal', 'alias', where
173 'builtin' and 'user' are the search defaults. Note that you should
174 not use quotes when specifying namespaces.
175
176 'Builtin' contains the python module builtin, 'user' contains all
177 user data, 'alias' only contain the shell aliases and no python
178 objects, 'internal' contains objects used by IPython. The
179 'user_global' namespace is only used by embedded IPython instances,
180 and it contains module-level globals. You can add namespaces to the
181 search with -s or exclude them with -e (these options can be given
182 more than once).
183
184 Examples
185 --------
186 ::
187
188 %psearch a* -> objects beginning with an a
189 %psearch -e builtin a* -> objects NOT in the builtin space starting in a
190 %psearch a* function -> all functions beginning with an a
191 %psearch re.e* -> objects beginning with an e in module re
192 %psearch r*.e* -> objects that start with e in modules starting in r
193 %psearch r*.* string -> all strings in modules beginning with r
194
195 Case sensitive search::
196
197 %psearch -c a* list all object beginning with lower case a
198
199 Show objects beginning with a single _::
200
201 %psearch -a _* list objects beginning with a single underscore
202 """
203 try:
204 parameter_s.encode('ascii')
205 except UnicodeEncodeError:
206 print 'Python identifiers can only contain ascii characters.'
207 return
208
209 # default namespaces to be searched
210 def_search = ['user_local', 'user_global', 'builtin']
211
212 # Process options/args
213 opts,args = self.parse_options(parameter_s,'cias:e:',list_all=True)
214 opt = opts.get
215 shell = self.shell
216 psearch = shell.inspector.psearch
217
218 # select case options
219 if opts.has_key('i'):
220 ignore_case = True
221 elif opts.has_key('c'):
222 ignore_case = False
223 else:
224 ignore_case = not shell.wildcards_case_sensitive
225
226 # Build list of namespaces to search from user options
227 def_search.extend(opt('s',[]))
228 ns_exclude = ns_exclude=opt('e',[])
229 ns_search = [nm for nm in def_search if nm not in ns_exclude]
230
231 # Call the actual search
232 try:
233 psearch(args,shell.ns_table,ns_search,
234 show_all=opt('a'),ignore_case=ignore_case)
235 except:
236 shell.showtraceback()
237
238 @skip_doctest
239 @line_magic
240 def who_ls(self, parameter_s=''):
241 """Return a sorted list of all interactive variables.
242
243 If arguments are given, only variables of types matching these
244 arguments are returned.
245
246 Examples
247 --------
248
249 Define two variables and list them with who_ls::
250
251 In [1]: alpha = 123
252
253 In [2]: beta = 'test'
254
255 In [3]: %who_ls
256 Out[3]: ['alpha', 'beta']
257
258 In [4]: %who_ls int
259 Out[4]: ['alpha']
260
261 In [5]: %who_ls str
262 Out[5]: ['beta']
263 """
264
265 user_ns = self.shell.user_ns
266 user_ns_hidden = self.shell.user_ns_hidden
267 out = [ i for i in user_ns
268 if not i.startswith('_') \
269 and not i in user_ns_hidden ]
270
271 typelist = parameter_s.split()
272 if typelist:
273 typeset = set(typelist)
274 out = [i for i in out if type(user_ns[i]).__name__ in typeset]
275
276 out.sort()
277 return out
278
279 @skip_doctest
280 @line_magic
281 def who(self, parameter_s=''):
282 """Print all interactive variables, with some minimal formatting.
283
284 If any arguments are given, only variables whose type matches one of
285 these are printed. For example::
286
287 %who function str
288
289 will only list functions and strings, excluding all other types of
290 variables. To find the proper type names, simply use type(var) at a
291 command line to see how python prints type names. For example:
292
293 ::
294
295 In [1]: type('hello')\\
296 Out[1]: <type 'str'>
297
298 indicates that the type name for strings is 'str'.
299
300 ``%who`` always excludes executed names loaded through your configuration
301 file and things which are internal to IPython.
302
303 This is deliberate, as typically you may load many modules and the
304 purpose of %who is to show you only what you've manually defined.
305
306 Examples
307 --------
308
309 Define two variables and list them with who::
310
311 In [1]: alpha = 123
312
313 In [2]: beta = 'test'
314
315 In [3]: %who
316 alpha beta
317
318 In [4]: %who int
319 alpha
320
321 In [5]: %who str
322 beta
323 """
324
325 varlist = self.who_ls(parameter_s)
326 if not varlist:
327 if parameter_s:
328 print 'No variables match your requested type.'
329 else:
330 print 'Interactive namespace is empty.'
331 return
332
333 # if we have variables, move on...
334 count = 0
335 for i in varlist:
336 print i+'\t',
337 count += 1
338 if count > 8:
339 count = 0
340 print
341 print
342
343 @skip_doctest
344 @line_magic
345 def whos(self, parameter_s=''):
346 """Like %who, but gives some extra information about each variable.
347
348 The same type filtering of %who can be applied here.
349
350 For all variables, the type is printed. Additionally it prints:
351
352 - For {},[],(): their length.
353
354 - For numpy arrays, a summary with shape, number of
355 elements, typecode and size in memory.
356
357 - Everything else: a string representation, snipping their middle if
358 too long.
359
360 Examples
361 --------
362
363 Define two variables and list them with whos::
364
365 In [1]: alpha = 123
366
367 In [2]: beta = 'test'
368
369 In [3]: %whos
370 Variable Type Data/Info
371 --------------------------------
372 alpha int 123
373 beta str test
374 """
375
376 varnames = self.who_ls(parameter_s)
377 if not varnames:
378 if parameter_s:
379 print 'No variables match your requested type.'
380 else:
381 print 'Interactive namespace is empty.'
382 return
383
384 # if we have variables, move on...
385
386 # for these types, show len() instead of data:
387 seq_types = ['dict', 'list', 'tuple']
388
389 # for numpy arrays, display summary info
390 ndarray_type = None
391 if 'numpy' in sys.modules:
392 try:
393 from numpy import ndarray
394 except ImportError:
395 pass
396 else:
397 ndarray_type = ndarray.__name__
398
399 # Find all variable names and types so we can figure out column sizes
400 def get_vars(i):
401 return self.shell.user_ns[i]
402
403 # some types are well known and can be shorter
404 abbrevs = {'IPython.core.macro.Macro' : 'Macro'}
405 def type_name(v):
406 tn = type(v).__name__
407 return abbrevs.get(tn,tn)
408
409 varlist = map(get_vars,varnames)
410
411 typelist = []
412 for vv in varlist:
413 tt = type_name(vv)
414
415 if tt=='instance':
416 typelist.append( abbrevs.get(str(vv.__class__),
417 str(vv.__class__)))
418 else:
419 typelist.append(tt)
420
421 # column labels and # of spaces as separator
422 varlabel = 'Variable'
423 typelabel = 'Type'
424 datalabel = 'Data/Info'
425 colsep = 3
426 # variable format strings
427 vformat = "{0:<{varwidth}}{1:<{typewidth}}"
428 aformat = "%s: %s elems, type `%s`, %s bytes"
429 # find the size of the columns to format the output nicely
430 varwidth = max(max(map(len,varnames)), len(varlabel)) + colsep
431 typewidth = max(max(map(len,typelist)), len(typelabel)) + colsep
432 # table header
433 print varlabel.ljust(varwidth) + typelabel.ljust(typewidth) + \
434 ' '+datalabel+'\n' + '-'*(varwidth+typewidth+len(datalabel)+1)
435 # and the table itself
436 kb = 1024
437 Mb = 1048576 # kb**2
438 for vname,var,vtype in zip(varnames,varlist,typelist):
439 print vformat.format(vname, vtype, varwidth=varwidth, typewidth=typewidth),
440 if vtype in seq_types:
441 print "n="+str(len(var))
442 elif vtype == ndarray_type:
443 vshape = str(var.shape).replace(',','').replace(' ','x')[1:-1]
444 if vtype==ndarray_type:
445 # numpy
446 vsize = var.size
447 vbytes = vsize*var.itemsize
448 vdtype = var.dtype
449
450 if vbytes < 100000:
451 print aformat % (vshape,vsize,vdtype,vbytes)
452 else:
453 print aformat % (vshape,vsize,vdtype,vbytes),
454 if vbytes < Mb:
455 print '(%s kb)' % (vbytes/kb,)
456 else:
457 print '(%s Mb)' % (vbytes/Mb,)
458 else:
459 try:
460 vstr = str(var)
461 except UnicodeEncodeError:
462 vstr = unicode(var).encode(DEFAULT_ENCODING,
463 'backslashreplace')
464 except:
465 vstr = "<object with id %d (str() failed)>" % id(var)
466 vstr = vstr.replace('\n','\\n')
467 if len(vstr) < 50:
468 print vstr
469 else:
470 print vstr[:25] + "<...>" + vstr[-25:]
471
472 @line_magic
473 def reset(self, parameter_s=''):
474 """Resets the namespace by removing all names defined by the user, if
475 called without arguments, or by removing some types of objects, such
476 as everything currently in IPython's In[] and Out[] containers (see
477 the parameters for details).
478
479 Parameters
480 ----------
481 -f : force reset without asking for confirmation.
482
483 -s : 'Soft' reset: Only clears your namespace, leaving history intact.
484 References to objects may be kept. By default (without this option),
485 we do a 'hard' reset, giving you a new session and removing all
486 references to objects from the current session.
487
488 in : reset input history
489
490 out : reset output history
491
492 dhist : reset directory history
493
494 array : reset only variables that are NumPy arrays
495
496 See Also
497 --------
498 magic_reset_selective : invoked as ``%reset_selective``
499
500 Examples
501 --------
502 ::
503
504 In [6]: a = 1
505
506 In [7]: a
507 Out[7]: 1
508
509 In [8]: 'a' in _ip.user_ns
510 Out[8]: True
511
512 In [9]: %reset -f
513
514 In [1]: 'a' in _ip.user_ns
515 Out[1]: False
516
517 In [2]: %reset -f in
518 Flushing input history
519
520 In [3]: %reset -f dhist in
521 Flushing directory history
522 Flushing input history
523
524 Notes
525 -----
526 Calling this magic from clients that do not implement standard input,
527 such as the ipython notebook interface, will reset the namespace
528 without confirmation.
529 """
530 opts, args = self.parse_options(parameter_s,'sf', mode='list')
531 if 'f' in opts:
532 ans = True
533 else:
534 try:
535 ans = self.shell.ask_yes_no(
536 "Once deleted, variables cannot be recovered. Proceed (y/[n])?",
537 default='n')
538 except StdinNotImplementedError:
539 ans = True
540 if not ans:
541 print 'Nothing done.'
542 return
543
544 if 's' in opts: # Soft reset
545 user_ns = self.shell.user_ns
546 for i in self.who_ls():
547 del(user_ns[i])
548 elif len(args) == 0: # Hard reset
549 self.shell.reset(new_session = False)
550
551 # reset in/out/dhist/array: previously extensinions/clearcmd.py
552 ip = self.shell
553 user_ns = self.shell.user_ns # local lookup, heavily used
554
555 for target in args:
556 target = target.lower() # make matches case insensitive
557 if target == 'out':
558 print "Flushing output cache (%d entries)" % len(user_ns['_oh'])
559 self.shell.displayhook.flush()
560
561 elif target == 'in':
562 print "Flushing input history"
563 pc = self.shell.displayhook.prompt_count + 1
564 for n in range(1, pc):
565 key = '_i'+repr(n)
566 user_ns.pop(key,None)
567 user_ns.update(dict(_i=u'',_ii=u'',_iii=u''))
568 hm = ip.history_manager
569 # don't delete these, as %save and %macro depending on the
570 # length of these lists to be preserved
571 hm.input_hist_parsed[:] = [''] * pc
572 hm.input_hist_raw[:] = [''] * pc
573 # hm has internal machinery for _i,_ii,_iii, clear it out
574 hm._i = hm._ii = hm._iii = hm._i00 = u''
575
576 elif target == 'array':
577 # Support cleaning up numpy arrays
578 try:
579 from numpy import ndarray
580 # This must be done with items and not iteritems because
581 # we're going to modify the dict in-place.
582 for x,val in user_ns.items():
583 if isinstance(val,ndarray):
584 del user_ns[x]
585 except ImportError:
586 print "reset array only works if Numpy is available."
587
588 elif target == 'dhist':
589 print "Flushing directory history"
590 del user_ns['_dh'][:]
591
592 else:
593 print "Don't know how to reset ",
594 print target + ", please run `%reset?` for details"
595
596 gc.collect()
597
598 @line_magic
599 def reset_selective(self, parameter_s=''):
600 """Resets the namespace by removing names defined by the user.
601
602 Input/Output history are left around in case you need them.
603
604 %reset_selective [-f] regex
605
606 No action is taken if regex is not included
607
608 Options
609 -f : force reset without asking for confirmation.
610
611 See Also
612 --------
613 magic_reset : invoked as ``%reset``
614
615 Examples
616 --------
617
618 We first fully reset the namespace so your output looks identical to
619 this example for pedagogical reasons; in practice you do not need a
620 full reset::
621
622 In [1]: %reset -f
623
624 Now, with a clean namespace we can make a few variables and use
625 ``%reset_selective`` to only delete names that match our regexp::
626
627 In [2]: a=1; b=2; c=3; b1m=4; b2m=5; b3m=6; b4m=7; b2s=8
628
629 In [3]: who_ls
630 Out[3]: ['a', 'b', 'b1m', 'b2m', 'b2s', 'b3m', 'b4m', 'c']
631
632 In [4]: %reset_selective -f b[2-3]m
633
634 In [5]: who_ls
635 Out[5]: ['a', 'b', 'b1m', 'b2s', 'b4m', 'c']
636
637 In [6]: %reset_selective -f d
638
639 In [7]: who_ls
640 Out[7]: ['a', 'b', 'b1m', 'b2s', 'b4m', 'c']
641
642 In [8]: %reset_selective -f c
643
644 In [9]: who_ls
645 Out[9]: ['a', 'b', 'b1m', 'b2s', 'b4m']
646
647 In [10]: %reset_selective -f b
648
649 In [11]: who_ls
650 Out[11]: ['a']
651
652 Notes
653 -----
654 Calling this magic from clients that do not implement standard input,
655 such as the ipython notebook interface, will reset the namespace
656 without confirmation.
657 """
658
659 opts, regex = self.parse_options(parameter_s,'f')
660
661 if opts.has_key('f'):
662 ans = True
663 else:
664 try:
665 ans = self.shell.ask_yes_no(
666 "Once deleted, variables cannot be recovered. Proceed (y/[n])? ",
667 default='n')
668 except StdinNotImplementedError:
669 ans = True
670 if not ans:
671 print 'Nothing done.'
672 return
673 user_ns = self.shell.user_ns
674 if not regex:
675 print 'No regex pattern specified. Nothing done.'
676 return
677 else:
678 try:
679 m = re.compile(regex)
680 except TypeError:
681 raise TypeError('regex must be a string or compiled pattern')
682 for i in self.who_ls():
683 if m.search(i):
684 del(user_ns[i])
685
686 @line_magic
687 def xdel(self, parameter_s=''):
688 """Delete a variable, trying to clear it from anywhere that
689 IPython's machinery has references to it. By default, this uses
690 the identity of the named object in the user namespace to remove
691 references held under other names. The object is also removed
692 from the output history.
693
694 Options
695 -n : Delete the specified name from all namespaces, without
696 checking their identity.
697 """
698 opts, varname = self.parse_options(parameter_s,'n')
699 try:
700 self.shell.del_var(varname, ('n' in opts))
701 except (NameError, ValueError) as e:
702 print type(e).__name__ +": "+ str(e)
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@@ -1,2951 +1,2951 b''
1 1 # -*- coding: utf-8 -*-
2 2 """Main IPython class."""
3 3
4 4 #-----------------------------------------------------------------------------
5 5 # Copyright (C) 2001 Janko Hauser <jhauser@zscout.de>
6 6 # Copyright (C) 2001-2007 Fernando Perez. <fperez@colorado.edu>
7 7 # Copyright (C) 2008-2011 The IPython Development Team
8 8 #
9 9 # Distributed under the terms of the BSD License. The full license is in
10 10 # the file COPYING, distributed as part of this software.
11 11 #-----------------------------------------------------------------------------
12 12
13 13 #-----------------------------------------------------------------------------
14 14 # Imports
15 15 #-----------------------------------------------------------------------------
16 16
17 17 from __future__ import with_statement
18 18 from __future__ import absolute_import
19 19
20 20 import __builtin__ as builtin_mod
21 21 import __future__
22 22 import abc
23 23 import ast
24 24 import atexit
25 25 import os
26 26 import re
27 27 import runpy
28 28 import sys
29 29 import tempfile
30 30 import types
31 31 import urllib
32 32 from io import open as io_open
33 33
34 34 from IPython.config.configurable import SingletonConfigurable
35 35 from IPython.core import debugger, oinspect
36 36 from IPython.core import history as ipcorehist
37 37 from IPython.core import magic
38 38 from IPython.core import page
39 39 from IPython.core import prefilter
40 40 from IPython.core import shadowns
41 41 from IPython.core import ultratb
42 42 from IPython.core.alias import AliasManager, AliasError
43 43 from IPython.core.autocall import ExitAutocall
44 44 from IPython.core.builtin_trap import BuiltinTrap
45 45 from IPython.core.compilerop import CachingCompiler
46 46 from IPython.core.display_trap import DisplayTrap
47 47 from IPython.core.displayhook import DisplayHook
48 48 from IPython.core.displaypub import DisplayPublisher
49 49 from IPython.core.error import UsageError
50 50 from IPython.core.extensions import ExtensionManager
51 51 from IPython.core.fakemodule import FakeModule, init_fakemod_dict
52 52 from IPython.core.formatters import DisplayFormatter
53 53 from IPython.core.history import HistoryManager
54 54 from IPython.core.inputsplitter import IPythonInputSplitter
55 55 from IPython.core.logger import Logger
56 56 from IPython.core.macro import Macro
57 57 from IPython.core.payload import PayloadManager
58 58 from IPython.core.plugin import PluginManager
59 59 from IPython.core.prefilter import PrefilterManager, ESC_MAGIC
60 60 from IPython.core.profiledir import ProfileDir
61 61 from IPython.core.pylabtools import pylab_activate
62 62 from IPython.core.prompts import PromptManager
63 63 from IPython.utils import PyColorize
64 64 from IPython.utils import io
65 65 from IPython.utils import py3compat
66 66 from IPython.utils import openpy
67 67 from IPython.utils.doctestreload import doctest_reload
68 68 from IPython.utils.io import ask_yes_no
69 69 from IPython.utils.ipstruct import Struct
70 70 from IPython.utils.path import get_home_dir, get_ipython_dir, get_py_filename, unquote_filename
71 71 from IPython.utils.pickleshare import PickleShareDB
72 72 from IPython.utils.process import system, getoutput
73 73 from IPython.utils.strdispatch import StrDispatch
74 74 from IPython.utils.syspathcontext import prepended_to_syspath
75 75 from IPython.utils.text import (format_screen, LSString, SList,
76 76 DollarFormatter)
77 77 from IPython.utils.traitlets import (Integer, CBool, CaselessStrEnum, Enum,
78 78 List, Unicode, Instance, Type)
79 79 from IPython.utils.warn import warn, error
80 80 import IPython.core.hooks
81 81
82 82 #-----------------------------------------------------------------------------
83 83 # Globals
84 84 #-----------------------------------------------------------------------------
85 85
86 86 # compiled regexps for autoindent management
87 87 dedent_re = re.compile(r'^\s+raise|^\s+return|^\s+pass')
88 88
89 89 #-----------------------------------------------------------------------------
90 90 # Utilities
91 91 #-----------------------------------------------------------------------------
92 92
93 93 def softspace(file, newvalue):
94 94 """Copied from code.py, to remove the dependency"""
95 95
96 96 oldvalue = 0
97 97 try:
98 98 oldvalue = file.softspace
99 99 except AttributeError:
100 100 pass
101 101 try:
102 102 file.softspace = newvalue
103 103 except (AttributeError, TypeError):
104 104 # "attribute-less object" or "read-only attributes"
105 105 pass
106 106 return oldvalue
107 107
108 108
109 109 def no_op(*a, **kw): pass
110 110
111 111 class NoOpContext(object):
112 112 def __enter__(self): pass
113 113 def __exit__(self, type, value, traceback): pass
114 114 no_op_context = NoOpContext()
115 115
116 116 class SpaceInInput(Exception): pass
117 117
118 118 class Bunch: pass
119 119
120 120
121 121 def get_default_colors():
122 122 if sys.platform=='darwin':
123 123 return "LightBG"
124 124 elif os.name=='nt':
125 125 return 'Linux'
126 126 else:
127 127 return 'Linux'
128 128
129 129
130 130 class SeparateUnicode(Unicode):
131 131 """A Unicode subclass to validate separate_in, separate_out, etc.
132 132
133 133 This is a Unicode based trait that converts '0'->'' and '\\n'->'\n'.
134 134 """
135 135
136 136 def validate(self, obj, value):
137 137 if value == '0': value = ''
138 138 value = value.replace('\\n','\n')
139 139 return super(SeparateUnicode, self).validate(obj, value)
140 140
141 141
142 142 class ReadlineNoRecord(object):
143 143 """Context manager to execute some code, then reload readline history
144 144 so that interactive input to the code doesn't appear when pressing up."""
145 145 def __init__(self, shell):
146 146 self.shell = shell
147 147 self._nested_level = 0
148 148
149 149 def __enter__(self):
150 150 if self._nested_level == 0:
151 151 try:
152 152 self.orig_length = self.current_length()
153 153 self.readline_tail = self.get_readline_tail()
154 154 except (AttributeError, IndexError): # Can fail with pyreadline
155 155 self.orig_length, self.readline_tail = 999999, []
156 156 self._nested_level += 1
157 157
158 158 def __exit__(self, type, value, traceback):
159 159 self._nested_level -= 1
160 160 if self._nested_level == 0:
161 161 # Try clipping the end if it's got longer
162 162 try:
163 163 e = self.current_length() - self.orig_length
164 164 if e > 0:
165 165 for _ in range(e):
166 166 self.shell.readline.remove_history_item(self.orig_length)
167 167
168 168 # If it still doesn't match, just reload readline history.
169 169 if self.current_length() != self.orig_length \
170 170 or self.get_readline_tail() != self.readline_tail:
171 171 self.shell.refill_readline_hist()
172 172 except (AttributeError, IndexError):
173 173 pass
174 174 # Returning False will cause exceptions to propagate
175 175 return False
176 176
177 177 def current_length(self):
178 178 return self.shell.readline.get_current_history_length()
179 179
180 180 def get_readline_tail(self, n=10):
181 181 """Get the last n items in readline history."""
182 182 end = self.shell.readline.get_current_history_length() + 1
183 183 start = max(end-n, 1)
184 184 ghi = self.shell.readline.get_history_item
185 185 return [ghi(x) for x in range(start, end)]
186 186
187 187 #-----------------------------------------------------------------------------
188 188 # Main IPython class
189 189 #-----------------------------------------------------------------------------
190 190
191 191 class InteractiveShell(SingletonConfigurable):
192 192 """An enhanced, interactive shell for Python."""
193 193
194 194 _instance = None
195 195
196 196 autocall = Enum((0,1,2), default_value=0, config=True, help=
197 197 """
198 198 Make IPython automatically call any callable object even if you didn't
199 199 type explicit parentheses. For example, 'str 43' becomes 'str(43)'
200 200 automatically. The value can be '0' to disable the feature, '1' for
201 201 'smart' autocall, where it is not applied if there are no more
202 202 arguments on the line, and '2' for 'full' autocall, where all callable
203 203 objects are automatically called (even if no arguments are present).
204 204 """
205 205 )
206 206 # TODO: remove all autoindent logic and put into frontends.
207 207 # We can't do this yet because even runlines uses the autoindent.
208 208 autoindent = CBool(True, config=True, help=
209 209 """
210 210 Autoindent IPython code entered interactively.
211 211 """
212 212 )
213 213 automagic = CBool(True, config=True, help=
214 214 """
215 215 Enable magic commands to be called without the leading %.
216 216 """
217 217 )
218 218 cache_size = Integer(1000, config=True, help=
219 219 """
220 220 Set the size of the output cache. The default is 1000, you can
221 221 change it permanently in your config file. Setting it to 0 completely
222 222 disables the caching system, and the minimum value accepted is 20 (if
223 223 you provide a value less than 20, it is reset to 0 and a warning is
224 224 issued). This limit is defined because otherwise you'll spend more
225 225 time re-flushing a too small cache than working
226 226 """
227 227 )
228 228 color_info = CBool(True, config=True, help=
229 229 """
230 230 Use colors for displaying information about objects. Because this
231 231 information is passed through a pager (like 'less'), and some pagers
232 232 get confused with color codes, this capability can be turned off.
233 233 """
234 234 )
235 235 colors = CaselessStrEnum(('NoColor','LightBG','Linux'),
236 236 default_value=get_default_colors(), config=True,
237 237 help="Set the color scheme (NoColor, Linux, or LightBG)."
238 238 )
239 239 colors_force = CBool(False, help=
240 240 """
241 241 Force use of ANSI color codes, regardless of OS and readline
242 242 availability.
243 243 """
244 244 # FIXME: This is essentially a hack to allow ZMQShell to show colors
245 245 # without readline on Win32. When the ZMQ formatting system is
246 246 # refactored, this should be removed.
247 247 )
248 248 debug = CBool(False, config=True)
249 249 deep_reload = CBool(False, config=True, help=
250 250 """
251 251 Enable deep (recursive) reloading by default. IPython can use the
252 252 deep_reload module which reloads changes in modules recursively (it
253 253 replaces the reload() function, so you don't need to change anything to
254 254 use it). deep_reload() forces a full reload of modules whose code may
255 255 have changed, which the default reload() function does not. When
256 256 deep_reload is off, IPython will use the normal reload(), but
257 257 deep_reload will still be available as dreload().
258 258 """
259 259 )
260 260 disable_failing_post_execute = CBool(False, config=True,
261 261 help="Don't call post-execute functions that have failed in the past."""
262 262 )
263 263 display_formatter = Instance(DisplayFormatter)
264 264 displayhook_class = Type(DisplayHook)
265 265 display_pub_class = Type(DisplayPublisher)
266 266
267 267 exit_now = CBool(False)
268 268 exiter = Instance(ExitAutocall)
269 269 def _exiter_default(self):
270 270 return ExitAutocall(self)
271 271 # Monotonically increasing execution counter
272 272 execution_count = Integer(1)
273 273 filename = Unicode("<ipython console>")
274 274 ipython_dir= Unicode('', config=True) # Set to get_ipython_dir() in __init__
275 275
276 276 # Input splitter, to split entire cells of input into either individual
277 277 # interactive statements or whole blocks.
278 278 input_splitter = Instance('IPython.core.inputsplitter.IPythonInputSplitter',
279 279 (), {})
280 280 logstart = CBool(False, config=True, help=
281 281 """
282 282 Start logging to the default log file.
283 283 """
284 284 )
285 285 logfile = Unicode('', config=True, help=
286 286 """
287 287 The name of the logfile to use.
288 288 """
289 289 )
290 290 logappend = Unicode('', config=True, help=
291 291 """
292 292 Start logging to the given file in append mode.
293 293 """
294 294 )
295 295 object_info_string_level = Enum((0,1,2), default_value=0,
296 296 config=True)
297 297 pdb = CBool(False, config=True, help=
298 298 """
299 299 Automatically call the pdb debugger after every exception.
300 300 """
301 301 )
302 302 multiline_history = CBool(sys.platform != 'win32', config=True,
303 303 help="Save multi-line entries as one entry in readline history"
304 304 )
305 305
306 306 # deprecated prompt traits:
307 307
308 308 prompt_in1 = Unicode('In [\\#]: ', config=True,
309 309 help="Deprecated, use PromptManager.in_template")
310 310 prompt_in2 = Unicode(' .\\D.: ', config=True,
311 311 help="Deprecated, use PromptManager.in2_template")
312 312 prompt_out = Unicode('Out[\\#]: ', config=True,
313 313 help="Deprecated, use PromptManager.out_template")
314 314 prompts_pad_left = CBool(True, config=True,
315 315 help="Deprecated, use PromptManager.justify")
316 316
317 317 def _prompt_trait_changed(self, name, old, new):
318 318 table = {
319 319 'prompt_in1' : 'in_template',
320 320 'prompt_in2' : 'in2_template',
321 321 'prompt_out' : 'out_template',
322 322 'prompts_pad_left' : 'justify',
323 323 }
324 324 warn("InteractiveShell.{name} is deprecated, use PromptManager.{newname}\n".format(
325 325 name=name, newname=table[name])
326 326 )
327 327 # protect against weird cases where self.config may not exist:
328 328 if self.config is not None:
329 329 # propagate to corresponding PromptManager trait
330 330 setattr(self.config.PromptManager, table[name], new)
331 331
332 332 _prompt_in1_changed = _prompt_trait_changed
333 333 _prompt_in2_changed = _prompt_trait_changed
334 334 _prompt_out_changed = _prompt_trait_changed
335 335 _prompt_pad_left_changed = _prompt_trait_changed
336 336
337 337 show_rewritten_input = CBool(True, config=True,
338 338 help="Show rewritten input, e.g. for autocall."
339 339 )
340 340
341 341 quiet = CBool(False, config=True)
342 342
343 343 history_length = Integer(10000, config=True)
344 344
345 345 # The readline stuff will eventually be moved to the terminal subclass
346 346 # but for now, we can't do that as readline is welded in everywhere.
347 347 readline_use = CBool(True, config=True)
348 348 readline_remove_delims = Unicode('-/~', config=True)
349 349 # don't use \M- bindings by default, because they
350 350 # conflict with 8-bit encodings. See gh-58,gh-88
351 351 readline_parse_and_bind = List([
352 352 'tab: complete',
353 353 '"\C-l": clear-screen',
354 354 'set show-all-if-ambiguous on',
355 355 '"\C-o": tab-insert',
356 356 '"\C-r": reverse-search-history',
357 357 '"\C-s": forward-search-history',
358 358 '"\C-p": history-search-backward',
359 359 '"\C-n": history-search-forward',
360 360 '"\e[A": history-search-backward',
361 361 '"\e[B": history-search-forward',
362 362 '"\C-k": kill-line',
363 363 '"\C-u": unix-line-discard',
364 364 ], allow_none=False, config=True)
365 365
366 366 # TODO: this part of prompt management should be moved to the frontends.
367 367 # Use custom TraitTypes that convert '0'->'' and '\\n'->'\n'
368 368 separate_in = SeparateUnicode('\n', config=True)
369 369 separate_out = SeparateUnicode('', config=True)
370 370 separate_out2 = SeparateUnicode('', config=True)
371 371 wildcards_case_sensitive = CBool(True, config=True)
372 372 xmode = CaselessStrEnum(('Context','Plain', 'Verbose'),
373 373 default_value='Context', config=True)
374 374
375 375 # Subcomponents of InteractiveShell
376 376 alias_manager = Instance('IPython.core.alias.AliasManager')
377 377 prefilter_manager = Instance('IPython.core.prefilter.PrefilterManager')
378 378 builtin_trap = Instance('IPython.core.builtin_trap.BuiltinTrap')
379 379 display_trap = Instance('IPython.core.display_trap.DisplayTrap')
380 380 extension_manager = Instance('IPython.core.extensions.ExtensionManager')
381 381 plugin_manager = Instance('IPython.core.plugin.PluginManager')
382 382 payload_manager = Instance('IPython.core.payload.PayloadManager')
383 383 history_manager = Instance('IPython.core.history.HistoryManager')
384 384 magics_manager = Instance('IPython.core.magic.MagicsManager')
385 385
386 386 profile_dir = Instance('IPython.core.application.ProfileDir')
387 387 @property
388 388 def profile(self):
389 389 if self.profile_dir is not None:
390 390 name = os.path.basename(self.profile_dir.location)
391 391 return name.replace('profile_','')
392 392
393 393
394 394 # Private interface
395 395 _post_execute = Instance(dict)
396 396
397 397 def __init__(self, config=None, ipython_dir=None, profile_dir=None,
398 398 user_module=None, user_ns=None,
399 399 custom_exceptions=((), None)):
400 400
401 401 # This is where traits with a config_key argument are updated
402 402 # from the values on config.
403 403 super(InteractiveShell, self).__init__(config=config)
404 404 self.configurables = [self]
405 405
406 406 # These are relatively independent and stateless
407 407 self.init_ipython_dir(ipython_dir)
408 408 self.init_profile_dir(profile_dir)
409 409 self.init_instance_attrs()
410 410 self.init_environment()
411 411
412 412 # Check if we're in a virtualenv, and set up sys.path.
413 413 self.init_virtualenv()
414 414
415 415 # Create namespaces (user_ns, user_global_ns, etc.)
416 416 self.init_create_namespaces(user_module, user_ns)
417 417 # This has to be done after init_create_namespaces because it uses
418 418 # something in self.user_ns, but before init_sys_modules, which
419 419 # is the first thing to modify sys.
420 420 # TODO: When we override sys.stdout and sys.stderr before this class
421 421 # is created, we are saving the overridden ones here. Not sure if this
422 422 # is what we want to do.
423 423 self.save_sys_module_state()
424 424 self.init_sys_modules()
425 425
426 426 # While we're trying to have each part of the code directly access what
427 427 # it needs without keeping redundant references to objects, we have too
428 428 # much legacy code that expects ip.db to exist.
429 429 self.db = PickleShareDB(os.path.join(self.profile_dir.location, 'db'))
430 430
431 431 self.init_history()
432 432 self.init_encoding()
433 433 self.init_prefilter()
434 434
435 435 self.init_syntax_highlighting()
436 436 self.init_hooks()
437 437 self.init_pushd_popd_magic()
438 438 # self.init_traceback_handlers use to be here, but we moved it below
439 439 # because it and init_io have to come after init_readline.
440 440 self.init_user_ns()
441 441 self.init_logger()
442 442 self.init_alias()
443 443 self.init_builtins()
444 444
445 445 # pre_config_initialization
446 446
447 447 # The next section should contain everything that was in ipmaker.
448 448 self.init_logstart()
449 449
450 450 # The following was in post_config_initialization
451 451 self.init_inspector()
452 452 # init_readline() must come before init_io(), because init_io uses
453 453 # readline related things.
454 454 self.init_readline()
455 455 # We save this here in case user code replaces raw_input, but it needs
456 456 # to be after init_readline(), because PyPy's readline works by replacing
457 457 # raw_input.
458 458 if py3compat.PY3:
459 459 self.raw_input_original = input
460 460 else:
461 461 self.raw_input_original = raw_input
462 462 # init_completer must come after init_readline, because it needs to
463 463 # know whether readline is present or not system-wide to configure the
464 464 # completers, since the completion machinery can now operate
465 465 # independently of readline (e.g. over the network)
466 466 self.init_completer()
467 467 # TODO: init_io() needs to happen before init_traceback handlers
468 468 # because the traceback handlers hardcode the stdout/stderr streams.
469 469 # This logic in in debugger.Pdb and should eventually be changed.
470 470 self.init_io()
471 471 self.init_traceback_handlers(custom_exceptions)
472 472 self.init_prompts()
473 473 self.init_display_formatter()
474 474 self.init_display_pub()
475 475 self.init_displayhook()
476 476 self.init_reload_doctest()
477 477 self.init_magics()
478 478 self.init_pdb()
479 479 self.init_extension_manager()
480 480 self.init_plugin_manager()
481 481 self.init_payload()
482 482 self.hooks.late_startup_hook()
483 483 atexit.register(self.atexit_operations)
484 484
485 485 def get_ipython(self):
486 486 """Return the currently running IPython instance."""
487 487 return self
488 488
489 489 #-------------------------------------------------------------------------
490 490 # Trait changed handlers
491 491 #-------------------------------------------------------------------------
492 492
493 493 def _ipython_dir_changed(self, name, new):
494 494 if not os.path.isdir(new):
495 495 os.makedirs(new, mode = 0777)
496 496
497 497 def set_autoindent(self,value=None):
498 498 """Set the autoindent flag, checking for readline support.
499 499
500 500 If called with no arguments, it acts as a toggle."""
501 501
502 502 if value != 0 and not self.has_readline:
503 503 if os.name == 'posix':
504 504 warn("The auto-indent feature requires the readline library")
505 505 self.autoindent = 0
506 506 return
507 507 if value is None:
508 508 self.autoindent = not self.autoindent
509 509 else:
510 510 self.autoindent = value
511 511
512 512 #-------------------------------------------------------------------------
513 513 # init_* methods called by __init__
514 514 #-------------------------------------------------------------------------
515 515
516 516 def init_ipython_dir(self, ipython_dir):
517 517 if ipython_dir is not None:
518 518 self.ipython_dir = ipython_dir
519 519 return
520 520
521 521 self.ipython_dir = get_ipython_dir()
522 522
523 523 def init_profile_dir(self, profile_dir):
524 524 if profile_dir is not None:
525 525 self.profile_dir = profile_dir
526 526 return
527 527 self.profile_dir =\
528 528 ProfileDir.create_profile_dir_by_name(self.ipython_dir, 'default')
529 529
530 530 def init_instance_attrs(self):
531 531 self.more = False
532 532
533 533 # command compiler
534 534 self.compile = CachingCompiler()
535 535
536 536 # Make an empty namespace, which extension writers can rely on both
537 537 # existing and NEVER being used by ipython itself. This gives them a
538 538 # convenient location for storing additional information and state
539 539 # their extensions may require, without fear of collisions with other
540 540 # ipython names that may develop later.
541 541 self.meta = Struct()
542 542
543 543 # Temporary files used for various purposes. Deleted at exit.
544 544 self.tempfiles = []
545 545
546 546 # Keep track of readline usage (later set by init_readline)
547 547 self.has_readline = False
548 548
549 549 # keep track of where we started running (mainly for crash post-mortem)
550 550 # This is not being used anywhere currently.
551 551 self.starting_dir = os.getcwdu()
552 552
553 553 # Indentation management
554 554 self.indent_current_nsp = 0
555 555
556 556 # Dict to track post-execution functions that have been registered
557 557 self._post_execute = {}
558 558
559 559 def init_environment(self):
560 560 """Any changes we need to make to the user's environment."""
561 561 pass
562 562
563 563 def init_encoding(self):
564 564 # Get system encoding at startup time. Certain terminals (like Emacs
565 565 # under Win32 have it set to None, and we need to have a known valid
566 566 # encoding to use in the raw_input() method
567 567 try:
568 568 self.stdin_encoding = sys.stdin.encoding or 'ascii'
569 569 except AttributeError:
570 570 self.stdin_encoding = 'ascii'
571 571
572 572 def init_syntax_highlighting(self):
573 573 # Python source parser/formatter for syntax highlighting
574 574 pyformat = PyColorize.Parser().format
575 575 self.pycolorize = lambda src: pyformat(src,'str',self.colors)
576 576
577 577 def init_pushd_popd_magic(self):
578 578 # for pushd/popd management
579 579 self.home_dir = get_home_dir()
580 580
581 581 self.dir_stack = []
582 582
583 583 def init_logger(self):
584 584 self.logger = Logger(self.home_dir, logfname='ipython_log.py',
585 585 logmode='rotate')
586 586
587 587 def init_logstart(self):
588 588 """Initialize logging in case it was requested at the command line.
589 589 """
590 590 if self.logappend:
591 591 self.magic('logstart %s append' % self.logappend)
592 592 elif self.logfile:
593 593 self.magic('logstart %' % self.logfile)
594 594 elif self.logstart:
595 595 self.magic('logstart')
596 596
597 597 def init_builtins(self):
598 598 # A single, static flag that we set to True. Its presence indicates
599 599 # that an IPython shell has been created, and we make no attempts at
600 600 # removing on exit or representing the existence of more than one
601 601 # IPython at a time.
602 602 builtin_mod.__dict__['__IPYTHON__'] = True
603 603
604 604 # In 0.11 we introduced '__IPYTHON__active' as an integer we'd try to
605 605 # manage on enter/exit, but with all our shells it's virtually
606 606 # impossible to get all the cases right. We're leaving the name in for
607 607 # those who adapted their codes to check for this flag, but will
608 608 # eventually remove it after a few more releases.
609 609 builtin_mod.__dict__['__IPYTHON__active'] = \
610 610 'Deprecated, check for __IPYTHON__'
611 611
612 612 self.builtin_trap = BuiltinTrap(shell=self)
613 613
614 614 def init_inspector(self):
615 615 # Object inspector
616 616 self.inspector = oinspect.Inspector(oinspect.InspectColors,
617 617 PyColorize.ANSICodeColors,
618 618 'NoColor',
619 619 self.object_info_string_level)
620 620
621 621 def init_io(self):
622 622 # This will just use sys.stdout and sys.stderr. If you want to
623 623 # override sys.stdout and sys.stderr themselves, you need to do that
624 624 # *before* instantiating this class, because io holds onto
625 625 # references to the underlying streams.
626 626 if sys.platform == 'win32' and self.has_readline:
627 627 io.stdout = io.stderr = io.IOStream(self.readline._outputfile)
628 628 else:
629 629 io.stdout = io.IOStream(sys.stdout)
630 630 io.stderr = io.IOStream(sys.stderr)
631 631
632 632 def init_prompts(self):
633 633 self.prompt_manager = PromptManager(shell=self, config=self.config)
634 634 self.configurables.append(self.prompt_manager)
635 635 # Set system prompts, so that scripts can decide if they are running
636 636 # interactively.
637 637 sys.ps1 = 'In : '
638 638 sys.ps2 = '...: '
639 639 sys.ps3 = 'Out: '
640 640
641 641 def init_display_formatter(self):
642 642 self.display_formatter = DisplayFormatter(config=self.config)
643 643 self.configurables.append(self.display_formatter)
644 644
645 645 def init_display_pub(self):
646 646 self.display_pub = self.display_pub_class(config=self.config)
647 647 self.configurables.append(self.display_pub)
648 648
649 649 def init_displayhook(self):
650 650 # Initialize displayhook, set in/out prompts and printing system
651 651 self.displayhook = self.displayhook_class(
652 652 config=self.config,
653 653 shell=self,
654 654 cache_size=self.cache_size,
655 655 )
656 656 self.configurables.append(self.displayhook)
657 657 # This is a context manager that installs/revmoes the displayhook at
658 658 # the appropriate time.
659 659 self.display_trap = DisplayTrap(hook=self.displayhook)
660 660
661 661 def init_reload_doctest(self):
662 662 # Do a proper resetting of doctest, including the necessary displayhook
663 663 # monkeypatching
664 664 try:
665 665 doctest_reload()
666 666 except ImportError:
667 667 warn("doctest module does not exist.")
668 668
669 669 def init_virtualenv(self):
670 670 """Add a virtualenv to sys.path so the user can import modules from it.
671 671 This isn't perfect: it doesn't use the Python interpreter with which the
672 672 virtualenv was built, and it ignores the --no-site-packages option. A
673 673 warning will appear suggesting the user installs IPython in the
674 674 virtualenv, but for many cases, it probably works well enough.
675 675
676 676 Adapted from code snippets online.
677 677
678 678 http://blog.ufsoft.org/2009/1/29/ipython-and-virtualenv
679 679 """
680 680 if 'VIRTUAL_ENV' not in os.environ:
681 681 # Not in a virtualenv
682 682 return
683 683
684 684 if sys.executable.startswith(os.environ['VIRTUAL_ENV']):
685 685 # Running properly in the virtualenv, don't need to do anything
686 686 return
687 687
688 688 warn("Attempting to work in a virtualenv. If you encounter problems, please "
689 689 "install IPython inside the virtualenv.\n")
690 690 if sys.platform == "win32":
691 691 virtual_env = os.path.join(os.environ['VIRTUAL_ENV'], 'Lib', 'site-packages')
692 692 else:
693 693 virtual_env = os.path.join(os.environ['VIRTUAL_ENV'], 'lib',
694 694 'python%d.%d' % sys.version_info[:2], 'site-packages')
695 695
696 696 import site
697 697 sys.path.insert(0, virtual_env)
698 698 site.addsitedir(virtual_env)
699 699
700 700 #-------------------------------------------------------------------------
701 701 # Things related to injections into the sys module
702 702 #-------------------------------------------------------------------------
703 703
704 704 def save_sys_module_state(self):
705 705 """Save the state of hooks in the sys module.
706 706
707 707 This has to be called after self.user_module is created.
708 708 """
709 709 self._orig_sys_module_state = {}
710 710 self._orig_sys_module_state['stdin'] = sys.stdin
711 711 self._orig_sys_module_state['stdout'] = sys.stdout
712 712 self._orig_sys_module_state['stderr'] = sys.stderr
713 713 self._orig_sys_module_state['excepthook'] = sys.excepthook
714 714 self._orig_sys_modules_main_name = self.user_module.__name__
715 715 self._orig_sys_modules_main_mod = sys.modules.get(self.user_module.__name__)
716 716
717 717 def restore_sys_module_state(self):
718 718 """Restore the state of the sys module."""
719 719 try:
720 720 for k, v in self._orig_sys_module_state.iteritems():
721 721 setattr(sys, k, v)
722 722 except AttributeError:
723 723 pass
724 724 # Reset what what done in self.init_sys_modules
725 725 if self._orig_sys_modules_main_mod is not None:
726 726 sys.modules[self._orig_sys_modules_main_name] = self._orig_sys_modules_main_mod
727 727
728 728 #-------------------------------------------------------------------------
729 729 # Things related to hooks
730 730 #-------------------------------------------------------------------------
731 731
732 732 def init_hooks(self):
733 733 # hooks holds pointers used for user-side customizations
734 734 self.hooks = Struct()
735 735
736 736 self.strdispatchers = {}
737 737
738 738 # Set all default hooks, defined in the IPython.hooks module.
739 739 hooks = IPython.core.hooks
740 740 for hook_name in hooks.__all__:
741 741 # default hooks have priority 100, i.e. low; user hooks should have
742 742 # 0-100 priority
743 743 self.set_hook(hook_name,getattr(hooks,hook_name), 100)
744 744
745 745 def set_hook(self,name,hook, priority = 50, str_key = None, re_key = None):
746 746 """set_hook(name,hook) -> sets an internal IPython hook.
747 747
748 748 IPython exposes some of its internal API as user-modifiable hooks. By
749 749 adding your function to one of these hooks, you can modify IPython's
750 750 behavior to call at runtime your own routines."""
751 751
752 752 # At some point in the future, this should validate the hook before it
753 753 # accepts it. Probably at least check that the hook takes the number
754 754 # of args it's supposed to.
755 755
756 756 f = types.MethodType(hook,self)
757 757
758 758 # check if the hook is for strdispatcher first
759 759 if str_key is not None:
760 760 sdp = self.strdispatchers.get(name, StrDispatch())
761 761 sdp.add_s(str_key, f, priority )
762 762 self.strdispatchers[name] = sdp
763 763 return
764 764 if re_key is not None:
765 765 sdp = self.strdispatchers.get(name, StrDispatch())
766 766 sdp.add_re(re.compile(re_key), f, priority )
767 767 self.strdispatchers[name] = sdp
768 768 return
769 769
770 770 dp = getattr(self.hooks, name, None)
771 771 if name not in IPython.core.hooks.__all__:
772 772 print "Warning! Hook '%s' is not one of %s" % \
773 773 (name, IPython.core.hooks.__all__ )
774 774 if not dp:
775 775 dp = IPython.core.hooks.CommandChainDispatcher()
776 776
777 777 try:
778 778 dp.add(f,priority)
779 779 except AttributeError:
780 780 # it was not commandchain, plain old func - replace
781 781 dp = f
782 782
783 783 setattr(self.hooks,name, dp)
784 784
785 785 def register_post_execute(self, func):
786 786 """Register a function for calling after code execution.
787 787 """
788 788 if not callable(func):
789 789 raise ValueError('argument %s must be callable' % func)
790 790 self._post_execute[func] = True
791 791
792 792 #-------------------------------------------------------------------------
793 793 # Things related to the "main" module
794 794 #-------------------------------------------------------------------------
795 795
796 796 def new_main_mod(self,ns=None):
797 797 """Return a new 'main' module object for user code execution.
798 798 """
799 799 main_mod = self._user_main_module
800 800 init_fakemod_dict(main_mod,ns)
801 801 return main_mod
802 802
803 803 def cache_main_mod(self,ns,fname):
804 804 """Cache a main module's namespace.
805 805
806 806 When scripts are executed via %run, we must keep a reference to the
807 807 namespace of their __main__ module (a FakeModule instance) around so
808 808 that Python doesn't clear it, rendering objects defined therein
809 809 useless.
810 810
811 811 This method keeps said reference in a private dict, keyed by the
812 812 absolute path of the module object (which corresponds to the script
813 813 path). This way, for multiple executions of the same script we only
814 814 keep one copy of the namespace (the last one), thus preventing memory
815 815 leaks from old references while allowing the objects from the last
816 816 execution to be accessible.
817 817
818 818 Note: we can not allow the actual FakeModule instances to be deleted,
819 819 because of how Python tears down modules (it hard-sets all their
820 820 references to None without regard for reference counts). This method
821 821 must therefore make a *copy* of the given namespace, to allow the
822 822 original module's __dict__ to be cleared and reused.
823 823
824 824
825 825 Parameters
826 826 ----------
827 827 ns : a namespace (a dict, typically)
828 828
829 829 fname : str
830 830 Filename associated with the namespace.
831 831
832 832 Examples
833 833 --------
834 834
835 835 In [10]: import IPython
836 836
837 837 In [11]: _ip.cache_main_mod(IPython.__dict__,IPython.__file__)
838 838
839 839 In [12]: IPython.__file__ in _ip._main_ns_cache
840 840 Out[12]: True
841 841 """
842 842 self._main_ns_cache[os.path.abspath(fname)] = ns.copy()
843 843
844 844 def clear_main_mod_cache(self):
845 845 """Clear the cache of main modules.
846 846
847 847 Mainly for use by utilities like %reset.
848 848
849 849 Examples
850 850 --------
851 851
852 852 In [15]: import IPython
853 853
854 854 In [16]: _ip.cache_main_mod(IPython.__dict__,IPython.__file__)
855 855
856 856 In [17]: len(_ip._main_ns_cache) > 0
857 857 Out[17]: True
858 858
859 859 In [18]: _ip.clear_main_mod_cache()
860 860
861 861 In [19]: len(_ip._main_ns_cache) == 0
862 862 Out[19]: True
863 863 """
864 864 self._main_ns_cache.clear()
865 865
866 866 #-------------------------------------------------------------------------
867 867 # Things related to debugging
868 868 #-------------------------------------------------------------------------
869 869
870 870 def init_pdb(self):
871 871 # Set calling of pdb on exceptions
872 872 # self.call_pdb is a property
873 873 self.call_pdb = self.pdb
874 874
875 875 def _get_call_pdb(self):
876 876 return self._call_pdb
877 877
878 878 def _set_call_pdb(self,val):
879 879
880 880 if val not in (0,1,False,True):
881 881 raise ValueError,'new call_pdb value must be boolean'
882 882
883 883 # store value in instance
884 884 self._call_pdb = val
885 885
886 886 # notify the actual exception handlers
887 887 self.InteractiveTB.call_pdb = val
888 888
889 889 call_pdb = property(_get_call_pdb,_set_call_pdb,None,
890 890 'Control auto-activation of pdb at exceptions')
891 891
892 892 def debugger(self,force=False):
893 893 """Call the pydb/pdb debugger.
894 894
895 895 Keywords:
896 896
897 897 - force(False): by default, this routine checks the instance call_pdb
898 898 flag and does not actually invoke the debugger if the flag is false.
899 899 The 'force' option forces the debugger to activate even if the flag
900 900 is false.
901 901 """
902 902
903 903 if not (force or self.call_pdb):
904 904 return
905 905
906 906 if not hasattr(sys,'last_traceback'):
907 907 error('No traceback has been produced, nothing to debug.')
908 908 return
909 909
910 910 # use pydb if available
911 911 if debugger.has_pydb:
912 912 from pydb import pm
913 913 else:
914 914 # fallback to our internal debugger
915 915 pm = lambda : self.InteractiveTB.debugger(force=True)
916 916
917 917 with self.readline_no_record:
918 918 pm()
919 919
920 920 #-------------------------------------------------------------------------
921 921 # Things related to IPython's various namespaces
922 922 #-------------------------------------------------------------------------
923 923 default_user_namespaces = True
924 924
925 925 def init_create_namespaces(self, user_module=None, user_ns=None):
926 926 # Create the namespace where the user will operate. user_ns is
927 927 # normally the only one used, and it is passed to the exec calls as
928 928 # the locals argument. But we do carry a user_global_ns namespace
929 929 # given as the exec 'globals' argument, This is useful in embedding
930 930 # situations where the ipython shell opens in a context where the
931 931 # distinction between locals and globals is meaningful. For
932 932 # non-embedded contexts, it is just the same object as the user_ns dict.
933 933
934 934 # FIXME. For some strange reason, __builtins__ is showing up at user
935 935 # level as a dict instead of a module. This is a manual fix, but I
936 936 # should really track down where the problem is coming from. Alex
937 937 # Schmolck reported this problem first.
938 938
939 939 # A useful post by Alex Martelli on this topic:
940 940 # Re: inconsistent value from __builtins__
941 941 # Von: Alex Martelli <aleaxit@yahoo.com>
942 942 # Datum: Freitag 01 Oktober 2004 04:45:34 nachmittags/abends
943 943 # Gruppen: comp.lang.python
944 944
945 945 # Michael Hohn <hohn@hooknose.lbl.gov> wrote:
946 946 # > >>> print type(builtin_check.get_global_binding('__builtins__'))
947 947 # > <type 'dict'>
948 948 # > >>> print type(__builtins__)
949 949 # > <type 'module'>
950 950 # > Is this difference in return value intentional?
951 951
952 952 # Well, it's documented that '__builtins__' can be either a dictionary
953 953 # or a module, and it's been that way for a long time. Whether it's
954 954 # intentional (or sensible), I don't know. In any case, the idea is
955 955 # that if you need to access the built-in namespace directly, you
956 956 # should start with "import __builtin__" (note, no 's') which will
957 957 # definitely give you a module. Yeah, it's somewhat confusing:-(.
958 958
959 959 # These routines return a properly built module and dict as needed by
960 960 # the rest of the code, and can also be used by extension writers to
961 961 # generate properly initialized namespaces.
962 962 if (user_ns is not None) or (user_module is not None):
963 963 self.default_user_namespaces = False
964 964 self.user_module, self.user_ns = self.prepare_user_module(user_module, user_ns)
965 965
966 966 # A record of hidden variables we have added to the user namespace, so
967 967 # we can list later only variables defined in actual interactive use.
968 968 self.user_ns_hidden = set()
969 969
970 970 # Now that FakeModule produces a real module, we've run into a nasty
971 971 # problem: after script execution (via %run), the module where the user
972 972 # code ran is deleted. Now that this object is a true module (needed
973 973 # so docetst and other tools work correctly), the Python module
974 974 # teardown mechanism runs over it, and sets to None every variable
975 975 # present in that module. Top-level references to objects from the
976 976 # script survive, because the user_ns is updated with them. However,
977 977 # calling functions defined in the script that use other things from
978 978 # the script will fail, because the function's closure had references
979 979 # to the original objects, which are now all None. So we must protect
980 980 # these modules from deletion by keeping a cache.
981 981 #
982 982 # To avoid keeping stale modules around (we only need the one from the
983 983 # last run), we use a dict keyed with the full path to the script, so
984 984 # only the last version of the module is held in the cache. Note,
985 985 # however, that we must cache the module *namespace contents* (their
986 986 # __dict__). Because if we try to cache the actual modules, old ones
987 987 # (uncached) could be destroyed while still holding references (such as
988 988 # those held by GUI objects that tend to be long-lived)>
989 989 #
990 990 # The %reset command will flush this cache. See the cache_main_mod()
991 991 # and clear_main_mod_cache() methods for details on use.
992 992
993 993 # This is the cache used for 'main' namespaces
994 994 self._main_ns_cache = {}
995 995 # And this is the single instance of FakeModule whose __dict__ we keep
996 996 # copying and clearing for reuse on each %run
997 997 self._user_main_module = FakeModule()
998 998
999 999 # A table holding all the namespaces IPython deals with, so that
1000 1000 # introspection facilities can search easily.
1001 1001 self.ns_table = {'user_global':self.user_module.__dict__,
1002 1002 'user_local':self.user_ns,
1003 1003 'builtin':builtin_mod.__dict__
1004 1004 }
1005 1005
1006 1006 @property
1007 1007 def user_global_ns(self):
1008 1008 return self.user_module.__dict__
1009 1009
1010 1010 def prepare_user_module(self, user_module=None, user_ns=None):
1011 1011 """Prepare the module and namespace in which user code will be run.
1012 1012
1013 1013 When IPython is started normally, both parameters are None: a new module
1014 1014 is created automatically, and its __dict__ used as the namespace.
1015 1015
1016 1016 If only user_module is provided, its __dict__ is used as the namespace.
1017 1017 If only user_ns is provided, a dummy module is created, and user_ns
1018 1018 becomes the global namespace. If both are provided (as they may be
1019 1019 when embedding), user_ns is the local namespace, and user_module
1020 1020 provides the global namespace.
1021 1021
1022 1022 Parameters
1023 1023 ----------
1024 1024 user_module : module, optional
1025 1025 The current user module in which IPython is being run. If None,
1026 1026 a clean module will be created.
1027 1027 user_ns : dict, optional
1028 1028 A namespace in which to run interactive commands.
1029 1029
1030 1030 Returns
1031 1031 -------
1032 1032 A tuple of user_module and user_ns, each properly initialised.
1033 1033 """
1034 1034 if user_module is None and user_ns is not None:
1035 1035 user_ns.setdefault("__name__", "__main__")
1036 1036 class DummyMod(object):
1037 1037 "A dummy module used for IPython's interactive namespace."
1038 1038 pass
1039 1039 user_module = DummyMod()
1040 1040 user_module.__dict__ = user_ns
1041 1041
1042 1042 if user_module is None:
1043 1043 user_module = types.ModuleType("__main__",
1044 1044 doc="Automatically created module for IPython interactive environment")
1045 1045
1046 1046 # We must ensure that __builtin__ (without the final 's') is always
1047 1047 # available and pointing to the __builtin__ *module*. For more details:
1048 1048 # http://mail.python.org/pipermail/python-dev/2001-April/014068.html
1049 1049 user_module.__dict__.setdefault('__builtin__', builtin_mod)
1050 1050 user_module.__dict__.setdefault('__builtins__', builtin_mod)
1051 1051
1052 1052 if user_ns is None:
1053 1053 user_ns = user_module.__dict__
1054 1054
1055 1055 return user_module, user_ns
1056 1056
1057 1057 def init_sys_modules(self):
1058 1058 # We need to insert into sys.modules something that looks like a
1059 1059 # module but which accesses the IPython namespace, for shelve and
1060 1060 # pickle to work interactively. Normally they rely on getting
1061 1061 # everything out of __main__, but for embedding purposes each IPython
1062 1062 # instance has its own private namespace, so we can't go shoving
1063 1063 # everything into __main__.
1064 1064
1065 1065 # note, however, that we should only do this for non-embedded
1066 1066 # ipythons, which really mimic the __main__.__dict__ with their own
1067 1067 # namespace. Embedded instances, on the other hand, should not do
1068 1068 # this because they need to manage the user local/global namespaces
1069 1069 # only, but they live within a 'normal' __main__ (meaning, they
1070 1070 # shouldn't overtake the execution environment of the script they're
1071 1071 # embedded in).
1072 1072
1073 1073 # This is overridden in the InteractiveShellEmbed subclass to a no-op.
1074 1074 main_name = self.user_module.__name__
1075 1075 sys.modules[main_name] = self.user_module
1076 1076
1077 1077 def init_user_ns(self):
1078 1078 """Initialize all user-visible namespaces to their minimum defaults.
1079 1079
1080 1080 Certain history lists are also initialized here, as they effectively
1081 1081 act as user namespaces.
1082 1082
1083 1083 Notes
1084 1084 -----
1085 1085 All data structures here are only filled in, they are NOT reset by this
1086 1086 method. If they were not empty before, data will simply be added to
1087 1087 therm.
1088 1088 """
1089 1089 # This function works in two parts: first we put a few things in
1090 1090 # user_ns, and we sync that contents into user_ns_hidden so that these
1091 1091 # initial variables aren't shown by %who. After the sync, we add the
1092 1092 # rest of what we *do* want the user to see with %who even on a new
1093 1093 # session (probably nothing, so theye really only see their own stuff)
1094 1094
1095 1095 # The user dict must *always* have a __builtin__ reference to the
1096 1096 # Python standard __builtin__ namespace, which must be imported.
1097 1097 # This is so that certain operations in prompt evaluation can be
1098 1098 # reliably executed with builtins. Note that we can NOT use
1099 1099 # __builtins__ (note the 's'), because that can either be a dict or a
1100 1100 # module, and can even mutate at runtime, depending on the context
1101 1101 # (Python makes no guarantees on it). In contrast, __builtin__ is
1102 1102 # always a module object, though it must be explicitly imported.
1103 1103
1104 1104 # For more details:
1105 1105 # http://mail.python.org/pipermail/python-dev/2001-April/014068.html
1106 1106 ns = dict()
1107 1107
1108 1108 # Put 'help' in the user namespace
1109 1109 try:
1110 1110 from site import _Helper
1111 1111 ns['help'] = _Helper()
1112 1112 except ImportError:
1113 1113 warn('help() not available - check site.py')
1114 1114
1115 1115 # make global variables for user access to the histories
1116 1116 ns['_ih'] = self.history_manager.input_hist_parsed
1117 1117 ns['_oh'] = self.history_manager.output_hist
1118 1118 ns['_dh'] = self.history_manager.dir_hist
1119 1119
1120 1120 ns['_sh'] = shadowns
1121 1121
1122 1122 # user aliases to input and output histories. These shouldn't show up
1123 1123 # in %who, as they can have very large reprs.
1124 1124 ns['In'] = self.history_manager.input_hist_parsed
1125 1125 ns['Out'] = self.history_manager.output_hist
1126 1126
1127 1127 # Store myself as the public api!!!
1128 1128 ns['get_ipython'] = self.get_ipython
1129 1129
1130 1130 ns['exit'] = self.exiter
1131 1131 ns['quit'] = self.exiter
1132 1132
1133 1133 # Sync what we've added so far to user_ns_hidden so these aren't seen
1134 1134 # by %who
1135 1135 self.user_ns_hidden.update(ns)
1136 1136
1137 1137 # Anything put into ns now would show up in %who. Think twice before
1138 1138 # putting anything here, as we really want %who to show the user their
1139 1139 # stuff, not our variables.
1140 1140
1141 1141 # Finally, update the real user's namespace
1142 1142 self.user_ns.update(ns)
1143 1143
1144 1144 @property
1145 1145 def all_ns_refs(self):
1146 1146 """Get a list of references to all the namespace dictionaries in which
1147 1147 IPython might store a user-created object.
1148 1148
1149 1149 Note that this does not include the displayhook, which also caches
1150 1150 objects from the output."""
1151 1151 return [self.user_ns, self.user_global_ns,
1152 1152 self._user_main_module.__dict__] + self._main_ns_cache.values()
1153 1153
1154 1154 def reset(self, new_session=True):
1155 1155 """Clear all internal namespaces, and attempt to release references to
1156 1156 user objects.
1157 1157
1158 1158 If new_session is True, a new history session will be opened.
1159 1159 """
1160 1160 # Clear histories
1161 1161 self.history_manager.reset(new_session)
1162 1162 # Reset counter used to index all histories
1163 1163 if new_session:
1164 1164 self.execution_count = 1
1165 1165
1166 1166 # Flush cached output items
1167 1167 if self.displayhook.do_full_cache:
1168 1168 self.displayhook.flush()
1169 1169
1170 1170 # The main execution namespaces must be cleared very carefully,
1171 1171 # skipping the deletion of the builtin-related keys, because doing so
1172 1172 # would cause errors in many object's __del__ methods.
1173 1173 if self.user_ns is not self.user_global_ns:
1174 1174 self.user_ns.clear()
1175 1175 ns = self.user_global_ns
1176 1176 drop_keys = set(ns.keys())
1177 1177 drop_keys.discard('__builtin__')
1178 1178 drop_keys.discard('__builtins__')
1179 1179 drop_keys.discard('__name__')
1180 1180 for k in drop_keys:
1181 1181 del ns[k]
1182 1182
1183 1183 self.user_ns_hidden.clear()
1184 1184
1185 1185 # Restore the user namespaces to minimal usability
1186 1186 self.init_user_ns()
1187 1187
1188 1188 # Restore the default and user aliases
1189 1189 self.alias_manager.clear_aliases()
1190 1190 self.alias_manager.init_aliases()
1191 1191
1192 1192 # Flush the private list of module references kept for script
1193 1193 # execution protection
1194 1194 self.clear_main_mod_cache()
1195 1195
1196 1196 # Clear out the namespace from the last %run
1197 1197 self.new_main_mod()
1198 1198
1199 1199 def del_var(self, varname, by_name=False):
1200 1200 """Delete a variable from the various namespaces, so that, as
1201 1201 far as possible, we're not keeping any hidden references to it.
1202 1202
1203 1203 Parameters
1204 1204 ----------
1205 1205 varname : str
1206 1206 The name of the variable to delete.
1207 1207 by_name : bool
1208 1208 If True, delete variables with the given name in each
1209 1209 namespace. If False (default), find the variable in the user
1210 1210 namespace, and delete references to it.
1211 1211 """
1212 1212 if varname in ('__builtin__', '__builtins__'):
1213 1213 raise ValueError("Refusing to delete %s" % varname)
1214 1214
1215 1215 ns_refs = self.all_ns_refs
1216 1216
1217 1217 if by_name: # Delete by name
1218 1218 for ns in ns_refs:
1219 1219 try:
1220 1220 del ns[varname]
1221 1221 except KeyError:
1222 1222 pass
1223 1223 else: # Delete by object
1224 1224 try:
1225 1225 obj = self.user_ns[varname]
1226 1226 except KeyError:
1227 1227 raise NameError("name '%s' is not defined" % varname)
1228 1228 # Also check in output history
1229 1229 ns_refs.append(self.history_manager.output_hist)
1230 1230 for ns in ns_refs:
1231 1231 to_delete = [n for n, o in ns.iteritems() if o is obj]
1232 1232 for name in to_delete:
1233 1233 del ns[name]
1234 1234
1235 1235 # displayhook keeps extra references, but not in a dictionary
1236 1236 for name in ('_', '__', '___'):
1237 1237 if getattr(self.displayhook, name) is obj:
1238 1238 setattr(self.displayhook, name, None)
1239 1239
1240 1240 def reset_selective(self, regex=None):
1241 1241 """Clear selective variables from internal namespaces based on a
1242 1242 specified regular expression.
1243 1243
1244 1244 Parameters
1245 1245 ----------
1246 1246 regex : string or compiled pattern, optional
1247 1247 A regular expression pattern that will be used in searching
1248 1248 variable names in the users namespaces.
1249 1249 """
1250 1250 if regex is not None:
1251 1251 try:
1252 1252 m = re.compile(regex)
1253 1253 except TypeError:
1254 1254 raise TypeError('regex must be a string or compiled pattern')
1255 1255 # Search for keys in each namespace that match the given regex
1256 1256 # If a match is found, delete the key/value pair.
1257 1257 for ns in self.all_ns_refs:
1258 1258 for var in ns:
1259 1259 if m.search(var):
1260 1260 del ns[var]
1261 1261
1262 1262 def push(self, variables, interactive=True):
1263 1263 """Inject a group of variables into the IPython user namespace.
1264 1264
1265 1265 Parameters
1266 1266 ----------
1267 1267 variables : dict, str or list/tuple of str
1268 1268 The variables to inject into the user's namespace. If a dict, a
1269 1269 simple update is done. If a str, the string is assumed to have
1270 1270 variable names separated by spaces. A list/tuple of str can also
1271 1271 be used to give the variable names. If just the variable names are
1272 1272 give (list/tuple/str) then the variable values looked up in the
1273 1273 callers frame.
1274 1274 interactive : bool
1275 1275 If True (default), the variables will be listed with the ``who``
1276 1276 magic.
1277 1277 """
1278 1278 vdict = None
1279 1279
1280 1280 # We need a dict of name/value pairs to do namespace updates.
1281 1281 if isinstance(variables, dict):
1282 1282 vdict = variables
1283 1283 elif isinstance(variables, (basestring, list, tuple)):
1284 1284 if isinstance(variables, basestring):
1285 1285 vlist = variables.split()
1286 1286 else:
1287 1287 vlist = variables
1288 1288 vdict = {}
1289 1289 cf = sys._getframe(1)
1290 1290 for name in vlist:
1291 1291 try:
1292 1292 vdict[name] = eval(name, cf.f_globals, cf.f_locals)
1293 1293 except:
1294 1294 print ('Could not get variable %s from %s' %
1295 1295 (name,cf.f_code.co_name))
1296 1296 else:
1297 1297 raise ValueError('variables must be a dict/str/list/tuple')
1298 1298
1299 1299 # Propagate variables to user namespace
1300 1300 self.user_ns.update(vdict)
1301 1301
1302 1302 # And configure interactive visibility
1303 1303 user_ns_hidden = self.user_ns_hidden
1304 1304 if interactive:
1305 1305 user_ns_hidden.difference_update(vdict)
1306 1306 else:
1307 1307 user_ns_hidden.update(vdict)
1308 1308
1309 1309 def drop_by_id(self, variables):
1310 1310 """Remove a dict of variables from the user namespace, if they are the
1311 1311 same as the values in the dictionary.
1312 1312
1313 1313 This is intended for use by extensions: variables that they've added can
1314 1314 be taken back out if they are unloaded, without removing any that the
1315 1315 user has overwritten.
1316 1316
1317 1317 Parameters
1318 1318 ----------
1319 1319 variables : dict
1320 1320 A dictionary mapping object names (as strings) to the objects.
1321 1321 """
1322 1322 for name, obj in variables.iteritems():
1323 1323 if name in self.user_ns and self.user_ns[name] is obj:
1324 1324 del self.user_ns[name]
1325 1325 self.user_ns_hidden.discard(name)
1326 1326
1327 1327 #-------------------------------------------------------------------------
1328 1328 # Things related to object introspection
1329 1329 #-------------------------------------------------------------------------
1330 1330
1331 1331 def _ofind(self, oname, namespaces=None):
1332 1332 """Find an object in the available namespaces.
1333 1333
1334 1334 self._ofind(oname) -> dict with keys: found,obj,ospace,ismagic
1335 1335
1336 1336 Has special code to detect magic functions.
1337 1337 """
1338 1338 oname = oname.strip()
1339 1339 #print '1- oname: <%r>' % oname # dbg
1340 1340 if not py3compat.isidentifier(oname.lstrip(ESC_MAGIC), dotted=True):
1341 1341 return dict(found=False)
1342 1342
1343 1343 alias_ns = None
1344 1344 if namespaces is None:
1345 1345 # Namespaces to search in:
1346 1346 # Put them in a list. The order is important so that we
1347 1347 # find things in the same order that Python finds them.
1348 1348 namespaces = [ ('Interactive', self.user_ns),
1349 1349 ('Interactive (global)', self.user_global_ns),
1350 1350 ('Python builtin', builtin_mod.__dict__),
1351 1351 ('Alias', self.alias_manager.alias_table),
1352 1352 ]
1353 1353 alias_ns = self.alias_manager.alias_table
1354 1354
1355 1355 # initialize results to 'null'
1356 1356 found = False; obj = None; ospace = None; ds = None;
1357 1357 ismagic = False; isalias = False; parent = None
1358 1358
1359 1359 # We need to special-case 'print', which as of python2.6 registers as a
1360 1360 # function but should only be treated as one if print_function was
1361 1361 # loaded with a future import. In this case, just bail.
1362 1362 if (oname == 'print' and not py3compat.PY3 and not \
1363 1363 (self.compile.compiler_flags & __future__.CO_FUTURE_PRINT_FUNCTION)):
1364 1364 return {'found':found, 'obj':obj, 'namespace':ospace,
1365 1365 'ismagic':ismagic, 'isalias':isalias, 'parent':parent}
1366 1366
1367 1367 # Look for the given name by splitting it in parts. If the head is
1368 1368 # found, then we look for all the remaining parts as members, and only
1369 1369 # declare success if we can find them all.
1370 1370 oname_parts = oname.split('.')
1371 1371 oname_head, oname_rest = oname_parts[0],oname_parts[1:]
1372 1372 for nsname,ns in namespaces:
1373 1373 try:
1374 1374 obj = ns[oname_head]
1375 1375 except KeyError:
1376 1376 continue
1377 1377 else:
1378 1378 #print 'oname_rest:', oname_rest # dbg
1379 1379 for part in oname_rest:
1380 1380 try:
1381 1381 parent = obj
1382 1382 obj = getattr(obj,part)
1383 1383 except:
1384 1384 # Blanket except b/c some badly implemented objects
1385 1385 # allow __getattr__ to raise exceptions other than
1386 1386 # AttributeError, which then crashes IPython.
1387 1387 break
1388 1388 else:
1389 1389 # If we finish the for loop (no break), we got all members
1390 1390 found = True
1391 1391 ospace = nsname
1392 1392 if ns == alias_ns:
1393 1393 isalias = True
1394 1394 break # namespace loop
1395 1395
1396 1396 # Try to see if it's magic
1397 1397 if not found:
1398 1398 if oname.startswith(ESC_MAGIC):
1399 1399 oname = oname[1:]
1400 1400 obj = self.find_magic(oname)
1401 1401 if obj is not None:
1402 1402 found = True
1403 1403 ospace = 'IPython internal'
1404 1404 ismagic = True
1405 1405
1406 1406 # Last try: special-case some literals like '', [], {}, etc:
1407 1407 if not found and oname_head in ["''",'""','[]','{}','()']:
1408 1408 obj = eval(oname_head)
1409 1409 found = True
1410 1410 ospace = 'Interactive'
1411 1411
1412 1412 return {'found':found, 'obj':obj, 'namespace':ospace,
1413 1413 'ismagic':ismagic, 'isalias':isalias, 'parent':parent}
1414 1414
1415 1415 def _ofind_property(self, oname, info):
1416 1416 """Second part of object finding, to look for property details."""
1417 1417 if info.found:
1418 1418 # Get the docstring of the class property if it exists.
1419 1419 path = oname.split('.')
1420 1420 root = '.'.join(path[:-1])
1421 1421 if info.parent is not None:
1422 1422 try:
1423 1423 target = getattr(info.parent, '__class__')
1424 1424 # The object belongs to a class instance.
1425 1425 try:
1426 1426 target = getattr(target, path[-1])
1427 1427 # The class defines the object.
1428 1428 if isinstance(target, property):
1429 1429 oname = root + '.__class__.' + path[-1]
1430 1430 info = Struct(self._ofind(oname))
1431 1431 except AttributeError: pass
1432 1432 except AttributeError: pass
1433 1433
1434 1434 # We return either the new info or the unmodified input if the object
1435 1435 # hadn't been found
1436 1436 return info
1437 1437
1438 1438 def _object_find(self, oname, namespaces=None):
1439 1439 """Find an object and return a struct with info about it."""
1440 1440 inf = Struct(self._ofind(oname, namespaces))
1441 1441 return Struct(self._ofind_property(oname, inf))
1442 1442
1443 1443 def _inspect(self, meth, oname, namespaces=None, **kw):
1444 1444 """Generic interface to the inspector system.
1445 1445
1446 1446 This function is meant to be called by pdef, pdoc & friends."""
1447 1447 info = self._object_find(oname)
1448 1448 if info.found:
1449 1449 pmethod = getattr(self.inspector, meth)
1450 1450 formatter = format_screen if info.ismagic else None
1451 1451 if meth == 'pdoc':
1452 1452 pmethod(info.obj, oname, formatter)
1453 1453 elif meth == 'pinfo':
1454 1454 pmethod(info.obj, oname, formatter, info, **kw)
1455 1455 else:
1456 1456 pmethod(info.obj, oname)
1457 1457 else:
1458 1458 print 'Object `%s` not found.' % oname
1459 1459 return 'not found' # so callers can take other action
1460 1460
1461 1461 def object_inspect(self, oname, detail_level=0):
1462 1462 with self.builtin_trap:
1463 1463 info = self._object_find(oname)
1464 1464 if info.found:
1465 1465 return self.inspector.info(info.obj, oname, info=info,
1466 1466 detail_level=detail_level
1467 1467 )
1468 1468 else:
1469 1469 return oinspect.object_info(name=oname, found=False)
1470 1470
1471 1471 #-------------------------------------------------------------------------
1472 1472 # Things related to history management
1473 1473 #-------------------------------------------------------------------------
1474 1474
1475 1475 def init_history(self):
1476 1476 """Sets up the command history, and starts regular autosaves."""
1477 1477 self.history_manager = HistoryManager(shell=self, config=self.config)
1478 1478 self.configurables.append(self.history_manager)
1479 1479
1480 1480 #-------------------------------------------------------------------------
1481 1481 # Things related to exception handling and tracebacks (not debugging)
1482 1482 #-------------------------------------------------------------------------
1483 1483
1484 1484 def init_traceback_handlers(self, custom_exceptions):
1485 1485 # Syntax error handler.
1486 1486 self.SyntaxTB = ultratb.SyntaxTB(color_scheme='NoColor')
1487 1487
1488 1488 # The interactive one is initialized with an offset, meaning we always
1489 1489 # want to remove the topmost item in the traceback, which is our own
1490 1490 # internal code. Valid modes: ['Plain','Context','Verbose']
1491 1491 self.InteractiveTB = ultratb.AutoFormattedTB(mode = 'Plain',
1492 1492 color_scheme='NoColor',
1493 1493 tb_offset = 1,
1494 1494 check_cache=self.compile.check_cache)
1495 1495
1496 1496 # The instance will store a pointer to the system-wide exception hook,
1497 1497 # so that runtime code (such as magics) can access it. This is because
1498 1498 # during the read-eval loop, it may get temporarily overwritten.
1499 1499 self.sys_excepthook = sys.excepthook
1500 1500
1501 1501 # and add any custom exception handlers the user may have specified
1502 1502 self.set_custom_exc(*custom_exceptions)
1503 1503
1504 1504 # Set the exception mode
1505 1505 self.InteractiveTB.set_mode(mode=self.xmode)
1506 1506
1507 1507 def set_custom_exc(self, exc_tuple, handler):
1508 1508 """set_custom_exc(exc_tuple,handler)
1509 1509
1510 1510 Set a custom exception handler, which will be called if any of the
1511 1511 exceptions in exc_tuple occur in the mainloop (specifically, in the
1512 1512 run_code() method).
1513 1513
1514 1514 Parameters
1515 1515 ----------
1516 1516
1517 1517 exc_tuple : tuple of exception classes
1518 1518 A *tuple* of exception classes, for which to call the defined
1519 1519 handler. It is very important that you use a tuple, and NOT A
1520 1520 LIST here, because of the way Python's except statement works. If
1521 1521 you only want to trap a single exception, use a singleton tuple::
1522 1522
1523 1523 exc_tuple == (MyCustomException,)
1524 1524
1525 1525 handler : callable
1526 1526 handler must have the following signature::
1527 1527
1528 1528 def my_handler(self, etype, value, tb, tb_offset=None):
1529 1529 ...
1530 1530 return structured_traceback
1531 1531
1532 1532 Your handler must return a structured traceback (a list of strings),
1533 1533 or None.
1534 1534
1535 1535 This will be made into an instance method (via types.MethodType)
1536 1536 of IPython itself, and it will be called if any of the exceptions
1537 1537 listed in the exc_tuple are caught. If the handler is None, an
1538 1538 internal basic one is used, which just prints basic info.
1539 1539
1540 1540 To protect IPython from crashes, if your handler ever raises an
1541 1541 exception or returns an invalid result, it will be immediately
1542 1542 disabled.
1543 1543
1544 1544 WARNING: by putting in your own exception handler into IPython's main
1545 1545 execution loop, you run a very good chance of nasty crashes. This
1546 1546 facility should only be used if you really know what you are doing."""
1547 1547
1548 1548 assert type(exc_tuple)==type(()) , \
1549 1549 "The custom exceptions must be given AS A TUPLE."
1550 1550
1551 1551 def dummy_handler(self,etype,value,tb,tb_offset=None):
1552 1552 print '*** Simple custom exception handler ***'
1553 1553 print 'Exception type :',etype
1554 1554 print 'Exception value:',value
1555 1555 print 'Traceback :',tb
1556 1556 #print 'Source code :','\n'.join(self.buffer)
1557 1557
1558 1558 def validate_stb(stb):
1559 1559 """validate structured traceback return type
1560 1560
1561 1561 return type of CustomTB *should* be a list of strings, but allow
1562 1562 single strings or None, which are harmless.
1563 1563
1564 1564 This function will *always* return a list of strings,
1565 1565 and will raise a TypeError if stb is inappropriate.
1566 1566 """
1567 1567 msg = "CustomTB must return list of strings, not %r" % stb
1568 1568 if stb is None:
1569 1569 return []
1570 1570 elif isinstance(stb, basestring):
1571 1571 return [stb]
1572 1572 elif not isinstance(stb, list):
1573 1573 raise TypeError(msg)
1574 1574 # it's a list
1575 1575 for line in stb:
1576 1576 # check every element
1577 1577 if not isinstance(line, basestring):
1578 1578 raise TypeError(msg)
1579 1579 return stb
1580 1580
1581 1581 if handler is None:
1582 1582 wrapped = dummy_handler
1583 1583 else:
1584 1584 def wrapped(self,etype,value,tb,tb_offset=None):
1585 1585 """wrap CustomTB handler, to protect IPython from user code
1586 1586
1587 1587 This makes it harder (but not impossible) for custom exception
1588 1588 handlers to crash IPython.
1589 1589 """
1590 1590 try:
1591 1591 stb = handler(self,etype,value,tb,tb_offset=tb_offset)
1592 1592 return validate_stb(stb)
1593 1593 except:
1594 1594 # clear custom handler immediately
1595 1595 self.set_custom_exc((), None)
1596 1596 print >> io.stderr, "Custom TB Handler failed, unregistering"
1597 1597 # show the exception in handler first
1598 1598 stb = self.InteractiveTB.structured_traceback(*sys.exc_info())
1599 1599 print >> io.stdout, self.InteractiveTB.stb2text(stb)
1600 1600 print >> io.stdout, "The original exception:"
1601 1601 stb = self.InteractiveTB.structured_traceback(
1602 1602 (etype,value,tb), tb_offset=tb_offset
1603 1603 )
1604 1604 return stb
1605 1605
1606 1606 self.CustomTB = types.MethodType(wrapped,self)
1607 1607 self.custom_exceptions = exc_tuple
1608 1608
1609 1609 def excepthook(self, etype, value, tb):
1610 1610 """One more defense for GUI apps that call sys.excepthook.
1611 1611
1612 1612 GUI frameworks like wxPython trap exceptions and call
1613 1613 sys.excepthook themselves. I guess this is a feature that
1614 1614 enables them to keep running after exceptions that would
1615 1615 otherwise kill their mainloop. This is a bother for IPython
1616 1616 which excepts to catch all of the program exceptions with a try:
1617 1617 except: statement.
1618 1618
1619 1619 Normally, IPython sets sys.excepthook to a CrashHandler instance, so if
1620 1620 any app directly invokes sys.excepthook, it will look to the user like
1621 1621 IPython crashed. In order to work around this, we can disable the
1622 1622 CrashHandler and replace it with this excepthook instead, which prints a
1623 1623 regular traceback using our InteractiveTB. In this fashion, apps which
1624 1624 call sys.excepthook will generate a regular-looking exception from
1625 1625 IPython, and the CrashHandler will only be triggered by real IPython
1626 1626 crashes.
1627 1627
1628 1628 This hook should be used sparingly, only in places which are not likely
1629 1629 to be true IPython errors.
1630 1630 """
1631 1631 self.showtraceback((etype,value,tb),tb_offset=0)
1632 1632
1633 1633 def _get_exc_info(self, exc_tuple=None):
1634 1634 """get exc_info from a given tuple, sys.exc_info() or sys.last_type etc.
1635 1635
1636 1636 Ensures sys.last_type,value,traceback hold the exc_info we found,
1637 1637 from whichever source.
1638 1638
1639 1639 raises ValueError if none of these contain any information
1640 1640 """
1641 1641 if exc_tuple is None:
1642 1642 etype, value, tb = sys.exc_info()
1643 1643 else:
1644 1644 etype, value, tb = exc_tuple
1645 1645
1646 1646 if etype is None:
1647 1647 if hasattr(sys, 'last_type'):
1648 1648 etype, value, tb = sys.last_type, sys.last_value, \
1649 1649 sys.last_traceback
1650 1650
1651 1651 if etype is None:
1652 1652 raise ValueError("No exception to find")
1653 1653
1654 1654 # Now store the exception info in sys.last_type etc.
1655 1655 # WARNING: these variables are somewhat deprecated and not
1656 1656 # necessarily safe to use in a threaded environment, but tools
1657 1657 # like pdb depend on their existence, so let's set them. If we
1658 1658 # find problems in the field, we'll need to revisit their use.
1659 1659 sys.last_type = etype
1660 1660 sys.last_value = value
1661 1661 sys.last_traceback = tb
1662 1662
1663 1663 return etype, value, tb
1664 1664
1665 1665
1666 1666 def showtraceback(self,exc_tuple = None,filename=None,tb_offset=None,
1667 1667 exception_only=False):
1668 1668 """Display the exception that just occurred.
1669 1669
1670 1670 If nothing is known about the exception, this is the method which
1671 1671 should be used throughout the code for presenting user tracebacks,
1672 1672 rather than directly invoking the InteractiveTB object.
1673 1673
1674 1674 A specific showsyntaxerror() also exists, but this method can take
1675 1675 care of calling it if needed, so unless you are explicitly catching a
1676 1676 SyntaxError exception, don't try to analyze the stack manually and
1677 1677 simply call this method."""
1678 1678
1679 1679 try:
1680 1680 try:
1681 1681 etype, value, tb = self._get_exc_info(exc_tuple)
1682 1682 except ValueError:
1683 1683 self.write_err('No traceback available to show.\n')
1684 1684 return
1685 1685
1686 1686 if etype is SyntaxError:
1687 1687 # Though this won't be called by syntax errors in the input
1688 1688 # line, there may be SyntaxError cases with imported code.
1689 1689 self.showsyntaxerror(filename)
1690 1690 elif etype is UsageError:
1691 1691 self.write_err("UsageError: %s" % value)
1692 1692 else:
1693 1693 if etype in self.custom_exceptions:
1694 1694 stb = self.CustomTB(etype, value, tb, tb_offset)
1695 1695 else:
1696 1696 if exception_only:
1697 1697 stb = ['An exception has occurred, use %tb to see '
1698 1698 'the full traceback.\n']
1699 1699 stb.extend(self.InteractiveTB.get_exception_only(etype,
1700 1700 value))
1701 1701 else:
1702 1702 stb = self.InteractiveTB.structured_traceback(etype,
1703 1703 value, tb, tb_offset=tb_offset)
1704 1704
1705 1705 self._showtraceback(etype, value, stb)
1706 1706 if self.call_pdb:
1707 1707 # drop into debugger
1708 1708 self.debugger(force=True)
1709 1709 return
1710 1710
1711 1711 # Actually show the traceback
1712 1712 self._showtraceback(etype, value, stb)
1713 1713
1714 1714 except KeyboardInterrupt:
1715 1715 self.write_err("\nKeyboardInterrupt\n")
1716 1716
1717 1717 def _showtraceback(self, etype, evalue, stb):
1718 1718 """Actually show a traceback.
1719 1719
1720 1720 Subclasses may override this method to put the traceback on a different
1721 1721 place, like a side channel.
1722 1722 """
1723 1723 print >> io.stdout, self.InteractiveTB.stb2text(stb)
1724 1724
1725 1725 def showsyntaxerror(self, filename=None):
1726 1726 """Display the syntax error that just occurred.
1727 1727
1728 1728 This doesn't display a stack trace because there isn't one.
1729 1729
1730 1730 If a filename is given, it is stuffed in the exception instead
1731 1731 of what was there before (because Python's parser always uses
1732 1732 "<string>" when reading from a string).
1733 1733 """
1734 1734 etype, value, last_traceback = self._get_exc_info()
1735 1735
1736 1736 if filename and etype is SyntaxError:
1737 1737 try:
1738 1738 value.filename = filename
1739 1739 except:
1740 1740 # Not the format we expect; leave it alone
1741 1741 pass
1742 1742
1743 1743 stb = self.SyntaxTB.structured_traceback(etype, value, [])
1744 1744 self._showtraceback(etype, value, stb)
1745 1745
1746 1746 # This is overridden in TerminalInteractiveShell to show a message about
1747 1747 # the %paste magic.
1748 1748 def showindentationerror(self):
1749 1749 """Called by run_cell when there's an IndentationError in code entered
1750 1750 at the prompt.
1751 1751
1752 1752 This is overridden in TerminalInteractiveShell to show a message about
1753 1753 the %paste magic."""
1754 1754 self.showsyntaxerror()
1755 1755
1756 1756 #-------------------------------------------------------------------------
1757 1757 # Things related to readline
1758 1758 #-------------------------------------------------------------------------
1759 1759
1760 1760 def init_readline(self):
1761 1761 """Command history completion/saving/reloading."""
1762 1762
1763 1763 if self.readline_use:
1764 1764 import IPython.utils.rlineimpl as readline
1765 1765
1766 1766 self.rl_next_input = None
1767 1767 self.rl_do_indent = False
1768 1768
1769 1769 if not self.readline_use or not readline.have_readline:
1770 1770 self.has_readline = False
1771 1771 self.readline = None
1772 1772 # Set a number of methods that depend on readline to be no-op
1773 1773 self.readline_no_record = no_op_context
1774 1774 self.set_readline_completer = no_op
1775 1775 self.set_custom_completer = no_op
1776 1776 self.set_completer_frame = no_op
1777 1777 if self.readline_use:
1778 1778 warn('Readline services not available or not loaded.')
1779 1779 else:
1780 1780 self.has_readline = True
1781 1781 self.readline = readline
1782 1782 sys.modules['readline'] = readline
1783 1783
1784 1784 # Platform-specific configuration
1785 1785 if os.name == 'nt':
1786 1786 # FIXME - check with Frederick to see if we can harmonize
1787 1787 # naming conventions with pyreadline to avoid this
1788 1788 # platform-dependent check
1789 1789 self.readline_startup_hook = readline.set_pre_input_hook
1790 1790 else:
1791 1791 self.readline_startup_hook = readline.set_startup_hook
1792 1792
1793 1793 # Load user's initrc file (readline config)
1794 1794 # Or if libedit is used, load editrc.
1795 1795 inputrc_name = os.environ.get('INPUTRC')
1796 1796 if inputrc_name is None:
1797 1797 inputrc_name = '.inputrc'
1798 1798 if readline.uses_libedit:
1799 1799 inputrc_name = '.editrc'
1800 1800 inputrc_name = os.path.join(self.home_dir, inputrc_name)
1801 1801 if os.path.isfile(inputrc_name):
1802 1802 try:
1803 1803 readline.read_init_file(inputrc_name)
1804 1804 except:
1805 1805 warn('Problems reading readline initialization file <%s>'
1806 1806 % inputrc_name)
1807 1807
1808 1808 # Configure readline according to user's prefs
1809 1809 # This is only done if GNU readline is being used. If libedit
1810 1810 # is being used (as on Leopard) the readline config is
1811 1811 # not run as the syntax for libedit is different.
1812 1812 if not readline.uses_libedit:
1813 1813 for rlcommand in self.readline_parse_and_bind:
1814 1814 #print "loading rl:",rlcommand # dbg
1815 1815 readline.parse_and_bind(rlcommand)
1816 1816
1817 1817 # Remove some chars from the delimiters list. If we encounter
1818 1818 # unicode chars, discard them.
1819 1819 delims = readline.get_completer_delims()
1820 1820 if not py3compat.PY3:
1821 1821 delims = delims.encode("ascii", "ignore")
1822 1822 for d in self.readline_remove_delims:
1823 1823 delims = delims.replace(d, "")
1824 1824 delims = delims.replace(ESC_MAGIC, '')
1825 1825 readline.set_completer_delims(delims)
1826 1826 # otherwise we end up with a monster history after a while:
1827 1827 readline.set_history_length(self.history_length)
1828 1828
1829 1829 self.refill_readline_hist()
1830 1830 self.readline_no_record = ReadlineNoRecord(self)
1831 1831
1832 1832 # Configure auto-indent for all platforms
1833 1833 self.set_autoindent(self.autoindent)
1834 1834
1835 1835 def refill_readline_hist(self):
1836 1836 # Load the last 1000 lines from history
1837 1837 self.readline.clear_history()
1838 1838 stdin_encoding = sys.stdin.encoding or "utf-8"
1839 1839 last_cell = u""
1840 1840 for _, _, cell in self.history_manager.get_tail(1000,
1841 1841 include_latest=True):
1842 1842 # Ignore blank lines and consecutive duplicates
1843 1843 cell = cell.rstrip()
1844 1844 if cell and (cell != last_cell):
1845 1845 if self.multiline_history:
1846 1846 self.readline.add_history(py3compat.unicode_to_str(cell,
1847 1847 stdin_encoding))
1848 1848 else:
1849 1849 for line in cell.splitlines():
1850 1850 self.readline.add_history(py3compat.unicode_to_str(line,
1851 1851 stdin_encoding))
1852 1852 last_cell = cell
1853 1853
1854 1854 def set_next_input(self, s):
1855 1855 """ Sets the 'default' input string for the next command line.
1856 1856
1857 1857 Requires readline.
1858 1858
1859 1859 Example:
1860 1860
1861 1861 [D:\ipython]|1> _ip.set_next_input("Hello Word")
1862 1862 [D:\ipython]|2> Hello Word_ # cursor is here
1863 1863 """
1864 1864 self.rl_next_input = py3compat.cast_bytes_py2(s)
1865 1865
1866 1866 # Maybe move this to the terminal subclass?
1867 1867 def pre_readline(self):
1868 1868 """readline hook to be used at the start of each line.
1869 1869
1870 1870 Currently it handles auto-indent only."""
1871 1871
1872 1872 if self.rl_do_indent:
1873 1873 self.readline.insert_text(self._indent_current_str())
1874 1874 if self.rl_next_input is not None:
1875 1875 self.readline.insert_text(self.rl_next_input)
1876 1876 self.rl_next_input = None
1877 1877
1878 1878 def _indent_current_str(self):
1879 1879 """return the current level of indentation as a string"""
1880 1880 return self.input_splitter.indent_spaces * ' '
1881 1881
1882 1882 #-------------------------------------------------------------------------
1883 1883 # Things related to text completion
1884 1884 #-------------------------------------------------------------------------
1885 1885
1886 1886 def init_completer(self):
1887 1887 """Initialize the completion machinery.
1888 1888
1889 1889 This creates completion machinery that can be used by client code,
1890 1890 either interactively in-process (typically triggered by the readline
1891 1891 library), programatically (such as in test suites) or out-of-prcess
1892 1892 (typically over the network by remote frontends).
1893 1893 """
1894 1894 from IPython.core.completer import IPCompleter
1895 1895 from IPython.core.completerlib import (module_completer,
1896 1896 magic_run_completer, cd_completer, reset_completer)
1897 1897
1898 1898 self.Completer = IPCompleter(shell=self,
1899 1899 namespace=self.user_ns,
1900 1900 global_namespace=self.user_global_ns,
1901 1901 alias_table=self.alias_manager.alias_table,
1902 1902 use_readline=self.has_readline,
1903 1903 config=self.config,
1904 1904 )
1905 1905 self.configurables.append(self.Completer)
1906 1906
1907 1907 # Add custom completers to the basic ones built into IPCompleter
1908 1908 sdisp = self.strdispatchers.get('complete_command', StrDispatch())
1909 1909 self.strdispatchers['complete_command'] = sdisp
1910 1910 self.Completer.custom_completers = sdisp
1911 1911
1912 1912 self.set_hook('complete_command', module_completer, str_key = 'import')
1913 1913 self.set_hook('complete_command', module_completer, str_key = 'from')
1914 1914 self.set_hook('complete_command', magic_run_completer, str_key = '%run')
1915 1915 self.set_hook('complete_command', cd_completer, str_key = '%cd')
1916 1916 self.set_hook('complete_command', reset_completer, str_key = '%reset')
1917 1917
1918 1918 # Only configure readline if we truly are using readline. IPython can
1919 1919 # do tab-completion over the network, in GUIs, etc, where readline
1920 1920 # itself may be absent
1921 1921 if self.has_readline:
1922 1922 self.set_readline_completer()
1923 1923
1924 1924 def complete(self, text, line=None, cursor_pos=None):
1925 1925 """Return the completed text and a list of completions.
1926 1926
1927 1927 Parameters
1928 1928 ----------
1929 1929
1930 1930 text : string
1931 1931 A string of text to be completed on. It can be given as empty and
1932 1932 instead a line/position pair are given. In this case, the
1933 1933 completer itself will split the line like readline does.
1934 1934
1935 1935 line : string, optional
1936 1936 The complete line that text is part of.
1937 1937
1938 1938 cursor_pos : int, optional
1939 1939 The position of the cursor on the input line.
1940 1940
1941 1941 Returns
1942 1942 -------
1943 1943 text : string
1944 1944 The actual text that was completed.
1945 1945
1946 1946 matches : list
1947 1947 A sorted list with all possible completions.
1948 1948
1949 1949 The optional arguments allow the completion to take more context into
1950 1950 account, and are part of the low-level completion API.
1951 1951
1952 1952 This is a wrapper around the completion mechanism, similar to what
1953 1953 readline does at the command line when the TAB key is hit. By
1954 1954 exposing it as a method, it can be used by other non-readline
1955 1955 environments (such as GUIs) for text completion.
1956 1956
1957 1957 Simple usage example:
1958 1958
1959 1959 In [1]: x = 'hello'
1960 1960
1961 1961 In [2]: _ip.complete('x.l')
1962 1962 Out[2]: ('x.l', ['x.ljust', 'x.lower', 'x.lstrip'])
1963 1963 """
1964 1964
1965 1965 # Inject names into __builtin__ so we can complete on the added names.
1966 1966 with self.builtin_trap:
1967 1967 return self.Completer.complete(text, line, cursor_pos)
1968 1968
1969 1969 def set_custom_completer(self, completer, pos=0):
1970 1970 """Adds a new custom completer function.
1971 1971
1972 1972 The position argument (defaults to 0) is the index in the completers
1973 1973 list where you want the completer to be inserted."""
1974 1974
1975 1975 newcomp = types.MethodType(completer,self.Completer)
1976 1976 self.Completer.matchers.insert(pos,newcomp)
1977 1977
1978 1978 def set_readline_completer(self):
1979 1979 """Reset readline's completer to be our own."""
1980 1980 self.readline.set_completer(self.Completer.rlcomplete)
1981 1981
1982 1982 def set_completer_frame(self, frame=None):
1983 1983 """Set the frame of the completer."""
1984 1984 if frame:
1985 1985 self.Completer.namespace = frame.f_locals
1986 1986 self.Completer.global_namespace = frame.f_globals
1987 1987 else:
1988 1988 self.Completer.namespace = self.user_ns
1989 1989 self.Completer.global_namespace = self.user_global_ns
1990 1990
1991 1991 #-------------------------------------------------------------------------
1992 1992 # Things related to magics
1993 1993 #-------------------------------------------------------------------------
1994 1994
1995 1995 def init_magics(self):
1996 1996 from IPython.core import magic_functions as mf
1997 1997 from IPython.core import magics as m
1998 1998 self.magics_manager = magic.MagicsManager(shell=self,
1999 1999 confg=self.config,
2000 2000 user_magics=m.UserMagics(self))
2001 2001 self.configurables.append(self.magics_manager)
2002 2002
2003 2003 # Expose as public API from the magics manager
2004 2004 self.register_magics = self.magics_manager.register
2005 2005 self.register_magic_function = self.magics_manager.register_function
2006 2006 self.define_magic = self.magics_manager.define_magic
2007 2007
2008 2008 self.register_magics(m.BasicMagics, m.CodeMagics, m.ConfigMagics,
2009 mf.ExecutionMagics, mf.NamespaceMagics, mf.AutoMagics,
2009 mf.ExecutionMagics, m.NamespaceMagics, mf.AutoMagics,
2010 2010 mf.OSMagics, mf.LoggingMagics, mf.ExtensionsMagics,
2011 2011 mf.PylabMagics, m.HistoryMagics, mf.DeprecatedMagics)
2012 2012
2013 2013 # FIXME: Move the color initialization to the DisplayHook, which
2014 2014 # should be split into a prompt manager and displayhook. We probably
2015 2015 # even need a centralize colors management object.
2016 2016 self.magic('colors %s' % self.colors)
2017 2017
2018 2018 def line_magic(self, magic_name, line, next_input=None):
2019 2019 """Execute the given line magic.
2020 2020
2021 2021 Parameters
2022 2022 ----------
2023 2023 magic_name : str
2024 2024 Name of the desired magic function, without '%' prefix.
2025 2025
2026 2026 line : str
2027 2027 The rest of the input line as a single string.
2028 2028
2029 2029 next_input : str, optional
2030 2030 Text to pre-load into the next input line.
2031 2031 """
2032 2032 # Allow setting the next input - this is used if the user does `a=abs?`.
2033 2033 # We do this first so that magic functions can override it.
2034 2034 if next_input:
2035 2035 self.set_next_input(next_input)
2036 2036
2037 2037 fn = self.find_line_magic(magic_name)
2038 2038 if fn is None:
2039 2039 error("Magic function `%s` not found." % magic_name)
2040 2040 else:
2041 2041 # Note: this is the distance in the stack to the user's frame.
2042 2042 # This will need to be updated if the internal calling logic gets
2043 2043 # refactored, or else we'll be expanding the wrong variables.
2044 2044 stack_depth = 2
2045 2045 magic_arg_s = self.var_expand(line, stack_depth)
2046 2046 # Put magic args in a list so we can call with f(*a) syntax
2047 2047 args = [magic_arg_s]
2048 2048 # Grab local namespace if we need it:
2049 2049 if getattr(fn, "needs_local_scope", False):
2050 2050 args.append(sys._getframe(stack_depth).f_locals)
2051 2051 with self.builtin_trap:
2052 2052 result = fn(*args)
2053 2053 return result
2054 2054
2055 2055 def cell_magic(self, magic_name, line, cell):
2056 2056 """Execute the given cell magic.
2057 2057 """
2058 2058 fn = self.find_cell_magic(magic_name)
2059 2059 if fn is None:
2060 2060 error("Magic function `%s` not found." % magic_name)
2061 2061 else:
2062 2062 # Note: this is the distance in the stack to the user's frame.
2063 2063 # This will need to be updated if the internal calling logic gets
2064 2064 # refactored, or else we'll be expanding the wrong variables.
2065 2065 stack_depth = 2
2066 2066 magic_arg_s = self.var_expand(line, stack_depth)
2067 2067 with self.builtin_trap:
2068 2068 result = fn(line, cell)
2069 2069 return result
2070 2070
2071 2071 def find_line_magic(self, magic_name):
2072 2072 """Find and return a line magic by name.
2073 2073
2074 2074 Returns None if the magic isn't found."""
2075 2075 return self.magics_manager.magics['line'].get(magic_name)
2076 2076
2077 2077 def find_cell_magic(self, magic_name):
2078 2078 """Find and return a cell magic by name.
2079 2079
2080 2080 Returns None if the magic isn't found."""
2081 2081 return self.magics_manager.magics['cell'].get(magic_name)
2082 2082
2083 2083 def find_magic(self, magic_name, magic_type='line'):
2084 2084 """Find and return a magic of the given type by name.
2085 2085
2086 2086 Returns None if the magic isn't found."""
2087 2087 return self.magics_manager.magics[magic_type].get(magic_name)
2088 2088
2089 2089 def magic(self, arg_s, next_input=None):
2090 2090 """DEPRECATED. Use line_magic() instead.
2091 2091
2092 2092 Call a magic function by name.
2093 2093
2094 2094 Input: a string containing the name of the magic function to call and
2095 2095 any additional arguments to be passed to the magic.
2096 2096
2097 2097 magic('name -opt foo bar') is equivalent to typing at the ipython
2098 2098 prompt:
2099 2099
2100 2100 In[1]: %name -opt foo bar
2101 2101
2102 2102 To call a magic without arguments, simply use magic('name').
2103 2103
2104 2104 This provides a proper Python function to call IPython's magics in any
2105 2105 valid Python code you can type at the interpreter, including loops and
2106 2106 compound statements.
2107 2107 """
2108 2108 # TODO: should we issue a loud deprecation warning here?
2109 2109 magic_name, _, magic_arg_s = arg_s.partition(' ')
2110 2110 magic_name = magic_name.lstrip(prefilter.ESC_MAGIC)
2111 2111 return self.line_magic(magic_name, magic_arg_s, next_input)
2112 2112
2113 2113 #-------------------------------------------------------------------------
2114 2114 # Things related to macros
2115 2115 #-------------------------------------------------------------------------
2116 2116
2117 2117 def define_macro(self, name, themacro):
2118 2118 """Define a new macro
2119 2119
2120 2120 Parameters
2121 2121 ----------
2122 2122 name : str
2123 2123 The name of the macro.
2124 2124 themacro : str or Macro
2125 2125 The action to do upon invoking the macro. If a string, a new
2126 2126 Macro object is created by passing the string to it.
2127 2127 """
2128 2128
2129 2129 from IPython.core import macro
2130 2130
2131 2131 if isinstance(themacro, basestring):
2132 2132 themacro = macro.Macro(themacro)
2133 2133 if not isinstance(themacro, macro.Macro):
2134 2134 raise ValueError('A macro must be a string or a Macro instance.')
2135 2135 self.user_ns[name] = themacro
2136 2136
2137 2137 #-------------------------------------------------------------------------
2138 2138 # Things related to the running of system commands
2139 2139 #-------------------------------------------------------------------------
2140 2140
2141 2141 def system_piped(self, cmd):
2142 2142 """Call the given cmd in a subprocess, piping stdout/err
2143 2143
2144 2144 Parameters
2145 2145 ----------
2146 2146 cmd : str
2147 2147 Command to execute (can not end in '&', as background processes are
2148 2148 not supported. Should not be a command that expects input
2149 2149 other than simple text.
2150 2150 """
2151 2151 if cmd.rstrip().endswith('&'):
2152 2152 # this is *far* from a rigorous test
2153 2153 # We do not support backgrounding processes because we either use
2154 2154 # pexpect or pipes to read from. Users can always just call
2155 2155 # os.system() or use ip.system=ip.system_raw
2156 2156 # if they really want a background process.
2157 2157 raise OSError("Background processes not supported.")
2158 2158
2159 2159 # we explicitly do NOT return the subprocess status code, because
2160 2160 # a non-None value would trigger :func:`sys.displayhook` calls.
2161 2161 # Instead, we store the exit_code in user_ns.
2162 2162 self.user_ns['_exit_code'] = system(self.var_expand(cmd, depth=2))
2163 2163
2164 2164 def system_raw(self, cmd):
2165 2165 """Call the given cmd in a subprocess using os.system
2166 2166
2167 2167 Parameters
2168 2168 ----------
2169 2169 cmd : str
2170 2170 Command to execute.
2171 2171 """
2172 2172 cmd = self.var_expand(cmd, depth=2)
2173 2173 # protect os.system from UNC paths on Windows, which it can't handle:
2174 2174 if sys.platform == 'win32':
2175 2175 from IPython.utils._process_win32 import AvoidUNCPath
2176 2176 with AvoidUNCPath() as path:
2177 2177 if path is not None:
2178 2178 cmd = '"pushd %s &&"%s' % (path, cmd)
2179 2179 cmd = py3compat.unicode_to_str(cmd)
2180 2180 ec = os.system(cmd)
2181 2181 else:
2182 2182 cmd = py3compat.unicode_to_str(cmd)
2183 2183 ec = os.system(cmd)
2184 2184
2185 2185 # We explicitly do NOT return the subprocess status code, because
2186 2186 # a non-None value would trigger :func:`sys.displayhook` calls.
2187 2187 # Instead, we store the exit_code in user_ns.
2188 2188 self.user_ns['_exit_code'] = ec
2189 2189
2190 2190 # use piped system by default, because it is better behaved
2191 2191 system = system_piped
2192 2192
2193 2193 def getoutput(self, cmd, split=True):
2194 2194 """Get output (possibly including stderr) from a subprocess.
2195 2195
2196 2196 Parameters
2197 2197 ----------
2198 2198 cmd : str
2199 2199 Command to execute (can not end in '&', as background processes are
2200 2200 not supported.
2201 2201 split : bool, optional
2202 2202
2203 2203 If True, split the output into an IPython SList. Otherwise, an
2204 2204 IPython LSString is returned. These are objects similar to normal
2205 2205 lists and strings, with a few convenience attributes for easier
2206 2206 manipulation of line-based output. You can use '?' on them for
2207 2207 details.
2208 2208 """
2209 2209 if cmd.rstrip().endswith('&'):
2210 2210 # this is *far* from a rigorous test
2211 2211 raise OSError("Background processes not supported.")
2212 2212 out = getoutput(self.var_expand(cmd, depth=2))
2213 2213 if split:
2214 2214 out = SList(out.splitlines())
2215 2215 else:
2216 2216 out = LSString(out)
2217 2217 return out
2218 2218
2219 2219 #-------------------------------------------------------------------------
2220 2220 # Things related to aliases
2221 2221 #-------------------------------------------------------------------------
2222 2222
2223 2223 def init_alias(self):
2224 2224 self.alias_manager = AliasManager(shell=self, config=self.config)
2225 2225 self.configurables.append(self.alias_manager)
2226 2226 self.ns_table['alias'] = self.alias_manager.alias_table,
2227 2227
2228 2228 #-------------------------------------------------------------------------
2229 2229 # Things related to extensions and plugins
2230 2230 #-------------------------------------------------------------------------
2231 2231
2232 2232 def init_extension_manager(self):
2233 2233 self.extension_manager = ExtensionManager(shell=self, config=self.config)
2234 2234 self.configurables.append(self.extension_manager)
2235 2235
2236 2236 def init_plugin_manager(self):
2237 2237 self.plugin_manager = PluginManager(config=self.config)
2238 2238 self.configurables.append(self.plugin_manager)
2239 2239
2240 2240
2241 2241 #-------------------------------------------------------------------------
2242 2242 # Things related to payloads
2243 2243 #-------------------------------------------------------------------------
2244 2244
2245 2245 def init_payload(self):
2246 2246 self.payload_manager = PayloadManager(config=self.config)
2247 2247 self.configurables.append(self.payload_manager)
2248 2248
2249 2249 #-------------------------------------------------------------------------
2250 2250 # Things related to the prefilter
2251 2251 #-------------------------------------------------------------------------
2252 2252
2253 2253 def init_prefilter(self):
2254 2254 self.prefilter_manager = PrefilterManager(shell=self, config=self.config)
2255 2255 self.configurables.append(self.prefilter_manager)
2256 2256 # Ultimately this will be refactored in the new interpreter code, but
2257 2257 # for now, we should expose the main prefilter method (there's legacy
2258 2258 # code out there that may rely on this).
2259 2259 self.prefilter = self.prefilter_manager.prefilter_lines
2260 2260
2261 2261 def auto_rewrite_input(self, cmd):
2262 2262 """Print to the screen the rewritten form of the user's command.
2263 2263
2264 2264 This shows visual feedback by rewriting input lines that cause
2265 2265 automatic calling to kick in, like::
2266 2266
2267 2267 /f x
2268 2268
2269 2269 into::
2270 2270
2271 2271 ------> f(x)
2272 2272
2273 2273 after the user's input prompt. This helps the user understand that the
2274 2274 input line was transformed automatically by IPython.
2275 2275 """
2276 2276 if not self.show_rewritten_input:
2277 2277 return
2278 2278
2279 2279 rw = self.prompt_manager.render('rewrite') + cmd
2280 2280
2281 2281 try:
2282 2282 # plain ascii works better w/ pyreadline, on some machines, so
2283 2283 # we use it and only print uncolored rewrite if we have unicode
2284 2284 rw = str(rw)
2285 2285 print >> io.stdout, rw
2286 2286 except UnicodeEncodeError:
2287 2287 print "------> " + cmd
2288 2288
2289 2289 #-------------------------------------------------------------------------
2290 2290 # Things related to extracting values/expressions from kernel and user_ns
2291 2291 #-------------------------------------------------------------------------
2292 2292
2293 2293 def _simple_error(self):
2294 2294 etype, value = sys.exc_info()[:2]
2295 2295 return u'[ERROR] {e.__name__}: {v}'.format(e=etype, v=value)
2296 2296
2297 2297 def user_variables(self, names):
2298 2298 """Get a list of variable names from the user's namespace.
2299 2299
2300 2300 Parameters
2301 2301 ----------
2302 2302 names : list of strings
2303 2303 A list of names of variables to be read from the user namespace.
2304 2304
2305 2305 Returns
2306 2306 -------
2307 2307 A dict, keyed by the input names and with the repr() of each value.
2308 2308 """
2309 2309 out = {}
2310 2310 user_ns = self.user_ns
2311 2311 for varname in names:
2312 2312 try:
2313 2313 value = repr(user_ns[varname])
2314 2314 except:
2315 2315 value = self._simple_error()
2316 2316 out[varname] = value
2317 2317 return out
2318 2318
2319 2319 def user_expressions(self, expressions):
2320 2320 """Evaluate a dict of expressions in the user's namespace.
2321 2321
2322 2322 Parameters
2323 2323 ----------
2324 2324 expressions : dict
2325 2325 A dict with string keys and string values. The expression values
2326 2326 should be valid Python expressions, each of which will be evaluated
2327 2327 in the user namespace.
2328 2328
2329 2329 Returns
2330 2330 -------
2331 2331 A dict, keyed like the input expressions dict, with the repr() of each
2332 2332 value.
2333 2333 """
2334 2334 out = {}
2335 2335 user_ns = self.user_ns
2336 2336 global_ns = self.user_global_ns
2337 2337 for key, expr in expressions.iteritems():
2338 2338 try:
2339 2339 value = repr(eval(expr, global_ns, user_ns))
2340 2340 except:
2341 2341 value = self._simple_error()
2342 2342 out[key] = value
2343 2343 return out
2344 2344
2345 2345 #-------------------------------------------------------------------------
2346 2346 # Things related to the running of code
2347 2347 #-------------------------------------------------------------------------
2348 2348
2349 2349 def ex(self, cmd):
2350 2350 """Execute a normal python statement in user namespace."""
2351 2351 with self.builtin_trap:
2352 2352 exec cmd in self.user_global_ns, self.user_ns
2353 2353
2354 2354 def ev(self, expr):
2355 2355 """Evaluate python expression expr in user namespace.
2356 2356
2357 2357 Returns the result of evaluation
2358 2358 """
2359 2359 with self.builtin_trap:
2360 2360 return eval(expr, self.user_global_ns, self.user_ns)
2361 2361
2362 2362 def safe_execfile(self, fname, *where, **kw):
2363 2363 """A safe version of the builtin execfile().
2364 2364
2365 2365 This version will never throw an exception, but instead print
2366 2366 helpful error messages to the screen. This only works on pure
2367 2367 Python files with the .py extension.
2368 2368
2369 2369 Parameters
2370 2370 ----------
2371 2371 fname : string
2372 2372 The name of the file to be executed.
2373 2373 where : tuple
2374 2374 One or two namespaces, passed to execfile() as (globals,locals).
2375 2375 If only one is given, it is passed as both.
2376 2376 exit_ignore : bool (False)
2377 2377 If True, then silence SystemExit for non-zero status (it is always
2378 2378 silenced for zero status, as it is so common).
2379 2379 raise_exceptions : bool (False)
2380 2380 If True raise exceptions everywhere. Meant for testing.
2381 2381
2382 2382 """
2383 2383 kw.setdefault('exit_ignore', False)
2384 2384 kw.setdefault('raise_exceptions', False)
2385 2385
2386 2386 fname = os.path.abspath(os.path.expanduser(fname))
2387 2387
2388 2388 # Make sure we can open the file
2389 2389 try:
2390 2390 with open(fname) as thefile:
2391 2391 pass
2392 2392 except:
2393 2393 warn('Could not open file <%s> for safe execution.' % fname)
2394 2394 return
2395 2395
2396 2396 # Find things also in current directory. This is needed to mimic the
2397 2397 # behavior of running a script from the system command line, where
2398 2398 # Python inserts the script's directory into sys.path
2399 2399 dname = os.path.dirname(fname)
2400 2400
2401 2401 with prepended_to_syspath(dname):
2402 2402 try:
2403 2403 py3compat.execfile(fname,*where)
2404 2404 except SystemExit, status:
2405 2405 # If the call was made with 0 or None exit status (sys.exit(0)
2406 2406 # or sys.exit() ), don't bother showing a traceback, as both of
2407 2407 # these are considered normal by the OS:
2408 2408 # > python -c'import sys;sys.exit(0)'; echo $?
2409 2409 # 0
2410 2410 # > python -c'import sys;sys.exit()'; echo $?
2411 2411 # 0
2412 2412 # For other exit status, we show the exception unless
2413 2413 # explicitly silenced, but only in short form.
2414 2414 if kw['raise_exceptions']:
2415 2415 raise
2416 2416 if status.code not in (0, None) and not kw['exit_ignore']:
2417 2417 self.showtraceback(exception_only=True)
2418 2418 except:
2419 2419 if kw['raise_exceptions']:
2420 2420 raise
2421 2421 self.showtraceback()
2422 2422
2423 2423 def safe_execfile_ipy(self, fname):
2424 2424 """Like safe_execfile, but for .ipy files with IPython syntax.
2425 2425
2426 2426 Parameters
2427 2427 ----------
2428 2428 fname : str
2429 2429 The name of the file to execute. The filename must have a
2430 2430 .ipy extension.
2431 2431 """
2432 2432 fname = os.path.abspath(os.path.expanduser(fname))
2433 2433
2434 2434 # Make sure we can open the file
2435 2435 try:
2436 2436 with open(fname) as thefile:
2437 2437 pass
2438 2438 except:
2439 2439 warn('Could not open file <%s> for safe execution.' % fname)
2440 2440 return
2441 2441
2442 2442 # Find things also in current directory. This is needed to mimic the
2443 2443 # behavior of running a script from the system command line, where
2444 2444 # Python inserts the script's directory into sys.path
2445 2445 dname = os.path.dirname(fname)
2446 2446
2447 2447 with prepended_to_syspath(dname):
2448 2448 try:
2449 2449 with open(fname) as thefile:
2450 2450 # self.run_cell currently captures all exceptions
2451 2451 # raised in user code. It would be nice if there were
2452 2452 # versions of runlines, execfile that did raise, so
2453 2453 # we could catch the errors.
2454 2454 self.run_cell(thefile.read(), store_history=False)
2455 2455 except:
2456 2456 self.showtraceback()
2457 2457 warn('Unknown failure executing file: <%s>' % fname)
2458 2458
2459 2459 def safe_run_module(self, mod_name, where):
2460 2460 """A safe version of runpy.run_module().
2461 2461
2462 2462 This version will never throw an exception, but instead print
2463 2463 helpful error messages to the screen.
2464 2464
2465 2465 Parameters
2466 2466 ----------
2467 2467 mod_name : string
2468 2468 The name of the module to be executed.
2469 2469 where : dict
2470 2470 The globals namespace.
2471 2471 """
2472 2472 try:
2473 2473 where.update(
2474 2474 runpy.run_module(str(mod_name), run_name="__main__",
2475 2475 alter_sys=True)
2476 2476 )
2477 2477 except:
2478 2478 self.showtraceback()
2479 2479 warn('Unknown failure executing module: <%s>' % mod_name)
2480 2480
2481 2481 def call_cell_magic(self, raw_cell, store_history=False):
2482 2482 line, _, cell = raw_cell.partition(os.linesep)
2483 2483 magic_name, _, line = line.partition(' ')
2484 2484 magic_name = magic_name.lstrip(prefilter.ESC_MAGIC)
2485 2485 return self.cell_magic(magic_name, line, cell)
2486 2486
2487 2487 def run_cell(self, raw_cell, store_history=False, silent=False):
2488 2488 """Run a complete IPython cell.
2489 2489
2490 2490 Parameters
2491 2491 ----------
2492 2492 raw_cell : str
2493 2493 The code (including IPython code such as %magic functions) to run.
2494 2494 store_history : bool
2495 2495 If True, the raw and translated cell will be stored in IPython's
2496 2496 history. For user code calling back into IPython's machinery, this
2497 2497 should be set to False.
2498 2498 silent : bool
2499 2499 If True, avoid side-effets, such as implicit displayhooks, history,
2500 2500 and logging. silent=True forces store_history=False.
2501 2501 """
2502 2502 if (not raw_cell) or raw_cell.isspace():
2503 2503 return
2504 2504
2505 2505 if silent:
2506 2506 store_history = False
2507 2507
2508 2508 if raw_cell.startswith('%%'):
2509 2509 return self.call_cell_magic(raw_cell, store_history)
2510 2510
2511 2511 for line in raw_cell.splitlines():
2512 2512 self.input_splitter.push(line)
2513 2513 cell = self.input_splitter.source_reset()
2514 2514
2515 2515 with self.builtin_trap:
2516 2516 prefilter_failed = False
2517 2517 if len(cell.splitlines()) == 1:
2518 2518 try:
2519 2519 # use prefilter_lines to handle trailing newlines
2520 2520 # restore trailing newline for ast.parse
2521 2521 cell = self.prefilter_manager.prefilter_lines(cell) + '\n'
2522 2522 except AliasError as e:
2523 2523 error(e)
2524 2524 prefilter_failed = True
2525 2525 except Exception:
2526 2526 # don't allow prefilter errors to crash IPython
2527 2527 self.showtraceback()
2528 2528 prefilter_failed = True
2529 2529
2530 2530 # Store raw and processed history
2531 2531 if store_history:
2532 2532 self.history_manager.store_inputs(self.execution_count,
2533 2533 cell, raw_cell)
2534 2534 if not silent:
2535 2535 self.logger.log(cell, raw_cell)
2536 2536
2537 2537 if not prefilter_failed:
2538 2538 # don't run if prefilter failed
2539 2539 cell_name = self.compile.cache(cell, self.execution_count)
2540 2540
2541 2541 with self.display_trap:
2542 2542 try:
2543 2543 code_ast = self.compile.ast_parse(cell,
2544 2544 filename=cell_name)
2545 2545 except IndentationError:
2546 2546 self.showindentationerror()
2547 2547 if store_history:
2548 2548 self.execution_count += 1
2549 2549 return None
2550 2550 except (OverflowError, SyntaxError, ValueError, TypeError,
2551 2551 MemoryError):
2552 2552 self.showsyntaxerror()
2553 2553 if store_history:
2554 2554 self.execution_count += 1
2555 2555 return None
2556 2556
2557 2557 interactivity = "none" if silent else "last_expr"
2558 2558 self.run_ast_nodes(code_ast.body, cell_name,
2559 2559 interactivity=interactivity)
2560 2560
2561 2561 # Execute any registered post-execution functions.
2562 2562 # unless we are silent
2563 2563 post_exec = [] if silent else self._post_execute.iteritems()
2564 2564
2565 2565 for func, status in post_exec:
2566 2566 if self.disable_failing_post_execute and not status:
2567 2567 continue
2568 2568 try:
2569 2569 func()
2570 2570 except KeyboardInterrupt:
2571 2571 print >> io.stderr, "\nKeyboardInterrupt"
2572 2572 except Exception:
2573 2573 # register as failing:
2574 2574 self._post_execute[func] = False
2575 2575 self.showtraceback()
2576 2576 print >> io.stderr, '\n'.join([
2577 2577 "post-execution function %r produced an error." % func,
2578 2578 "If this problem persists, you can disable failing post-exec functions with:",
2579 2579 "",
2580 2580 " get_ipython().disable_failing_post_execute = True"
2581 2581 ])
2582 2582
2583 2583 if store_history:
2584 2584 # Write output to the database. Does nothing unless
2585 2585 # history output logging is enabled.
2586 2586 self.history_manager.store_output(self.execution_count)
2587 2587 # Each cell is a *single* input, regardless of how many lines it has
2588 2588 self.execution_count += 1
2589 2589
2590 2590 def run_ast_nodes(self, nodelist, cell_name, interactivity='last_expr'):
2591 2591 """Run a sequence of AST nodes. The execution mode depends on the
2592 2592 interactivity parameter.
2593 2593
2594 2594 Parameters
2595 2595 ----------
2596 2596 nodelist : list
2597 2597 A sequence of AST nodes to run.
2598 2598 cell_name : str
2599 2599 Will be passed to the compiler as the filename of the cell. Typically
2600 2600 the value returned by ip.compile.cache(cell).
2601 2601 interactivity : str
2602 2602 'all', 'last', 'last_expr' or 'none', specifying which nodes should be
2603 2603 run interactively (displaying output from expressions). 'last_expr'
2604 2604 will run the last node interactively only if it is an expression (i.e.
2605 2605 expressions in loops or other blocks are not displayed. Other values
2606 2606 for this parameter will raise a ValueError.
2607 2607 """
2608 2608 if not nodelist:
2609 2609 return
2610 2610
2611 2611 if interactivity == 'last_expr':
2612 2612 if isinstance(nodelist[-1], ast.Expr):
2613 2613 interactivity = "last"
2614 2614 else:
2615 2615 interactivity = "none"
2616 2616
2617 2617 if interactivity == 'none':
2618 2618 to_run_exec, to_run_interactive = nodelist, []
2619 2619 elif interactivity == 'last':
2620 2620 to_run_exec, to_run_interactive = nodelist[:-1], nodelist[-1:]
2621 2621 elif interactivity == 'all':
2622 2622 to_run_exec, to_run_interactive = [], nodelist
2623 2623 else:
2624 2624 raise ValueError("Interactivity was %r" % interactivity)
2625 2625
2626 2626 exec_count = self.execution_count
2627 2627
2628 2628 try:
2629 2629 for i, node in enumerate(to_run_exec):
2630 2630 mod = ast.Module([node])
2631 2631 code = self.compile(mod, cell_name, "exec")
2632 2632 if self.run_code(code):
2633 2633 return True
2634 2634
2635 2635 for i, node in enumerate(to_run_interactive):
2636 2636 mod = ast.Interactive([node])
2637 2637 code = self.compile(mod, cell_name, "single")
2638 2638 if self.run_code(code):
2639 2639 return True
2640 2640
2641 2641 # Flush softspace
2642 2642 if softspace(sys.stdout, 0):
2643 2643 print
2644 2644
2645 2645 except:
2646 2646 # It's possible to have exceptions raised here, typically by
2647 2647 # compilation of odd code (such as a naked 'return' outside a
2648 2648 # function) that did parse but isn't valid. Typically the exception
2649 2649 # is a SyntaxError, but it's safest just to catch anything and show
2650 2650 # the user a traceback.
2651 2651
2652 2652 # We do only one try/except outside the loop to minimize the impact
2653 2653 # on runtime, and also because if any node in the node list is
2654 2654 # broken, we should stop execution completely.
2655 2655 self.showtraceback()
2656 2656
2657 2657 return False
2658 2658
2659 2659 def run_code(self, code_obj):
2660 2660 """Execute a code object.
2661 2661
2662 2662 When an exception occurs, self.showtraceback() is called to display a
2663 2663 traceback.
2664 2664
2665 2665 Parameters
2666 2666 ----------
2667 2667 code_obj : code object
2668 2668 A compiled code object, to be executed
2669 2669
2670 2670 Returns
2671 2671 -------
2672 2672 False : successful execution.
2673 2673 True : an error occurred.
2674 2674 """
2675 2675
2676 2676 # Set our own excepthook in case the user code tries to call it
2677 2677 # directly, so that the IPython crash handler doesn't get triggered
2678 2678 old_excepthook,sys.excepthook = sys.excepthook, self.excepthook
2679 2679
2680 2680 # we save the original sys.excepthook in the instance, in case config
2681 2681 # code (such as magics) needs access to it.
2682 2682 self.sys_excepthook = old_excepthook
2683 2683 outflag = 1 # happens in more places, so it's easier as default
2684 2684 try:
2685 2685 try:
2686 2686 self.hooks.pre_run_code_hook()
2687 2687 #rprint('Running code', repr(code_obj)) # dbg
2688 2688 exec code_obj in self.user_global_ns, self.user_ns
2689 2689 finally:
2690 2690 # Reset our crash handler in place
2691 2691 sys.excepthook = old_excepthook
2692 2692 except SystemExit:
2693 2693 self.showtraceback(exception_only=True)
2694 2694 warn("To exit: use 'exit', 'quit', or Ctrl-D.", level=1)
2695 2695 except self.custom_exceptions:
2696 2696 etype,value,tb = sys.exc_info()
2697 2697 self.CustomTB(etype,value,tb)
2698 2698 except:
2699 2699 self.showtraceback()
2700 2700 else:
2701 2701 outflag = 0
2702 2702 return outflag
2703 2703
2704 2704 # For backwards compatibility
2705 2705 runcode = run_code
2706 2706
2707 2707 #-------------------------------------------------------------------------
2708 2708 # Things related to GUI support and pylab
2709 2709 #-------------------------------------------------------------------------
2710 2710
2711 2711 def enable_gui(self, gui=None):
2712 2712 raise NotImplementedError('Implement enable_gui in a subclass')
2713 2713
2714 2714 def enable_pylab(self, gui=None, import_all=True):
2715 2715 """Activate pylab support at runtime.
2716 2716
2717 2717 This turns on support for matplotlib, preloads into the interactive
2718 2718 namespace all of numpy and pylab, and configures IPython to correctly
2719 2719 interact with the GUI event loop. The GUI backend to be used can be
2720 2720 optionally selected with the optional :param:`gui` argument.
2721 2721
2722 2722 Parameters
2723 2723 ----------
2724 2724 gui : optional, string
2725 2725
2726 2726 If given, dictates the choice of matplotlib GUI backend to use
2727 2727 (should be one of IPython's supported backends, 'qt', 'osx', 'tk',
2728 2728 'gtk', 'wx' or 'inline'), otherwise we use the default chosen by
2729 2729 matplotlib (as dictated by the matplotlib build-time options plus the
2730 2730 user's matplotlibrc configuration file). Note that not all backends
2731 2731 make sense in all contexts, for example a terminal ipython can't
2732 2732 display figures inline.
2733 2733 """
2734 2734 from IPython.core.pylabtools import mpl_runner
2735 2735 # We want to prevent the loading of pylab to pollute the user's
2736 2736 # namespace as shown by the %who* magics, so we execute the activation
2737 2737 # code in an empty namespace, and we update *both* user_ns and
2738 2738 # user_ns_hidden with this information.
2739 2739 ns = {}
2740 2740 try:
2741 2741 gui = pylab_activate(ns, gui, import_all, self)
2742 2742 except KeyError:
2743 2743 error("Backend %r not supported" % gui)
2744 2744 return
2745 2745 self.user_ns.update(ns)
2746 2746 self.user_ns_hidden.update(ns)
2747 2747 # Now we must activate the gui pylab wants to use, and fix %run to take
2748 2748 # plot updates into account
2749 2749 self.enable_gui(gui)
2750 2750 self.magics_manager.registry['ExecutionMagics'].default_runner = \
2751 2751 mpl_runner(self.safe_execfile)
2752 2752
2753 2753 #-------------------------------------------------------------------------
2754 2754 # Utilities
2755 2755 #-------------------------------------------------------------------------
2756 2756
2757 2757 def var_expand(self, cmd, depth=0, formatter=DollarFormatter()):
2758 2758 """Expand python variables in a string.
2759 2759
2760 2760 The depth argument indicates how many frames above the caller should
2761 2761 be walked to look for the local namespace where to expand variables.
2762 2762
2763 2763 The global namespace for expansion is always the user's interactive
2764 2764 namespace.
2765 2765 """
2766 2766 ns = self.user_ns.copy()
2767 2767 ns.update(sys._getframe(depth+1).f_locals)
2768 2768 ns.pop('self', None)
2769 2769 try:
2770 2770 cmd = formatter.format(cmd, **ns)
2771 2771 except Exception:
2772 2772 # if formatter couldn't format, just let it go untransformed
2773 2773 pass
2774 2774 return cmd
2775 2775
2776 2776 def mktempfile(self, data=None, prefix='ipython_edit_'):
2777 2777 """Make a new tempfile and return its filename.
2778 2778
2779 2779 This makes a call to tempfile.mktemp, but it registers the created
2780 2780 filename internally so ipython cleans it up at exit time.
2781 2781
2782 2782 Optional inputs:
2783 2783
2784 2784 - data(None): if data is given, it gets written out to the temp file
2785 2785 immediately, and the file is closed again."""
2786 2786
2787 2787 filename = tempfile.mktemp('.py', prefix)
2788 2788 self.tempfiles.append(filename)
2789 2789
2790 2790 if data:
2791 2791 tmp_file = open(filename,'w')
2792 2792 tmp_file.write(data)
2793 2793 tmp_file.close()
2794 2794 return filename
2795 2795
2796 2796 # TODO: This should be removed when Term is refactored.
2797 2797 def write(self,data):
2798 2798 """Write a string to the default output"""
2799 2799 io.stdout.write(data)
2800 2800
2801 2801 # TODO: This should be removed when Term is refactored.
2802 2802 def write_err(self,data):
2803 2803 """Write a string to the default error output"""
2804 2804 io.stderr.write(data)
2805 2805
2806 2806 def ask_yes_no(self, prompt, default=None):
2807 2807 if self.quiet:
2808 2808 return True
2809 2809 return ask_yes_no(prompt,default)
2810 2810
2811 2811 def show_usage(self):
2812 2812 """Show a usage message"""
2813 2813 page.page(IPython.core.usage.interactive_usage)
2814 2814
2815 2815 def extract_input_lines(self, range_str, raw=False):
2816 2816 """Return as a string a set of input history slices.
2817 2817
2818 2818 Parameters
2819 2819 ----------
2820 2820 range_str : string
2821 2821 The set of slices is given as a string, like "~5/6-~4/2 4:8 9",
2822 2822 since this function is for use by magic functions which get their
2823 2823 arguments as strings. The number before the / is the session
2824 2824 number: ~n goes n back from the current session.
2825 2825
2826 2826 Optional Parameters:
2827 2827 - raw(False): by default, the processed input is used. If this is
2828 2828 true, the raw input history is used instead.
2829 2829
2830 2830 Note that slices can be called with two notations:
2831 2831
2832 2832 N:M -> standard python form, means including items N...(M-1).
2833 2833
2834 2834 N-M -> include items N..M (closed endpoint)."""
2835 2835 lines = self.history_manager.get_range_by_str(range_str, raw=raw)
2836 2836 return "\n".join(x for _, _, x in lines)
2837 2837
2838 2838 def find_user_code(self, target, raw=True, py_only=False):
2839 2839 """Get a code string from history, file, url, or a string or macro.
2840 2840
2841 2841 This is mainly used by magic functions.
2842 2842
2843 2843 Parameters
2844 2844 ----------
2845 2845
2846 2846 target : str
2847 2847
2848 2848 A string specifying code to retrieve. This will be tried respectively
2849 2849 as: ranges of input history (see %history for syntax), url,
2850 2850 correspnding .py file, filename, or an expression evaluating to a
2851 2851 string or Macro in the user namespace.
2852 2852
2853 2853 raw : bool
2854 2854 If true (default), retrieve raw history. Has no effect on the other
2855 2855 retrieval mechanisms.
2856 2856
2857 2857 py_only : bool (default False)
2858 2858 Only try to fetch python code, do not try alternative methods to decode file
2859 2859 if unicode fails.
2860 2860
2861 2861 Returns
2862 2862 -------
2863 2863 A string of code.
2864 2864
2865 2865 ValueError is raised if nothing is found, and TypeError if it evaluates
2866 2866 to an object of another type. In each case, .args[0] is a printable
2867 2867 message.
2868 2868 """
2869 2869 code = self.extract_input_lines(target, raw=raw) # Grab history
2870 2870 if code:
2871 2871 return code
2872 2872 utarget = unquote_filename(target)
2873 2873 try:
2874 2874 if utarget.startswith(('http://', 'https://')):
2875 2875 return openpy.read_py_url(utarget, skip_encoding_cookie=True)
2876 2876 except UnicodeDecodeError:
2877 2877 if not py_only :
2878 2878 response = urllib.urlopen(target)
2879 2879 return response.read().decode('latin1')
2880 2880 raise ValueError(("'%s' seem to be unreadable.") % utarget)
2881 2881
2882 2882 potential_target = [target]
2883 2883 try :
2884 2884 potential_target.insert(0,get_py_filename(target))
2885 2885 except IOError:
2886 2886 pass
2887 2887
2888 2888 for tgt in potential_target :
2889 2889 if os.path.isfile(tgt): # Read file
2890 2890 try :
2891 2891 return openpy.read_py_file(tgt, skip_encoding_cookie=True)
2892 2892 except UnicodeDecodeError :
2893 2893 if not py_only :
2894 2894 with io_open(tgt,'r', encoding='latin1') as f :
2895 2895 return f.read()
2896 2896 raise ValueError(("'%s' seem to be unreadable.") % target)
2897 2897
2898 2898 try: # User namespace
2899 2899 codeobj = eval(target, self.user_ns)
2900 2900 except Exception:
2901 2901 raise ValueError(("'%s' was not found in history, as a file, url, "
2902 2902 "nor in the user namespace.") % target)
2903 2903 if isinstance(codeobj, basestring):
2904 2904 return codeobj
2905 2905 elif isinstance(codeobj, Macro):
2906 2906 return codeobj.value
2907 2907
2908 2908 raise TypeError("%s is neither a string nor a macro." % target,
2909 2909 codeobj)
2910 2910
2911 2911 #-------------------------------------------------------------------------
2912 2912 # Things related to IPython exiting
2913 2913 #-------------------------------------------------------------------------
2914 2914 def atexit_operations(self):
2915 2915 """This will be executed at the time of exit.
2916 2916
2917 2917 Cleanup operations and saving of persistent data that is done
2918 2918 unconditionally by IPython should be performed here.
2919 2919
2920 2920 For things that may depend on startup flags or platform specifics (such
2921 2921 as having readline or not), register a separate atexit function in the
2922 2922 code that has the appropriate information, rather than trying to
2923 2923 clutter
2924 2924 """
2925 2925 # Close the history session (this stores the end time and line count)
2926 2926 # this must be *before* the tempfile cleanup, in case of temporary
2927 2927 # history db
2928 2928 self.history_manager.end_session()
2929 2929
2930 2930 # Cleanup all tempfiles left around
2931 2931 for tfile in self.tempfiles:
2932 2932 try:
2933 2933 os.unlink(tfile)
2934 2934 except OSError:
2935 2935 pass
2936 2936
2937 2937 # Clear all user namespaces to release all references cleanly.
2938 2938 self.reset(new_session=False)
2939 2939
2940 2940 # Run user hooks
2941 2941 self.hooks.shutdown_hook()
2942 2942
2943 2943 def cleanup(self):
2944 2944 self.restore_sys_module_state()
2945 2945
2946 2946
2947 2947 class InteractiveShellABC(object):
2948 2948 """An abstract base class for InteractiveShell."""
2949 2949 __metaclass__ = abc.ABCMeta
2950 2950
2951 2951 InteractiveShellABC.register(InteractiveShell)
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@@ -1,2676 +1,2004 b''
1 1 """Magic functions for InteractiveShell.
2 2 """
3 3
4 4 #-----------------------------------------------------------------------------
5 5 # Copyright (C) 2001 Janko Hauser <jhauser@zscout.de> and
6 6 # Copyright (C) 2001 Fernando Perez <fperez@colorado.edu>
7 7 # Copyright (C) 2008 The IPython Development Team
8 8
9 9 # Distributed under the terms of the BSD License. The full license is in
10 10 # the file COPYING, distributed as part of this software.
11 11 #-----------------------------------------------------------------------------
12 12
13 13 #-----------------------------------------------------------------------------
14 14 # Imports
15 15 #-----------------------------------------------------------------------------
16 16
17 17 # Stdlib
18 18 import __builtin__ as builtin_mod
19 19 import bdb
20 20 import gc
21 21 import inspect
22 22 import io
23 23 import json
24 24 import os
25 25 import re
26 26 import sys
27 27 import time
28 28 from StringIO import StringIO
29 29 from pprint import pformat
30 30 from urllib2 import urlopen
31 31
32 32 # cProfile was added in Python2.5
33 33 try:
34 34 import cProfile as profile
35 35 import pstats
36 36 except ImportError:
37 37 # profile isn't bundled by default in Debian for license reasons
38 38 try:
39 39 import profile, pstats
40 40 except ImportError:
41 41 profile = pstats = None
42 42
43 43 # Our own packages
44 44 from IPython.config.application import Application
45 45 from IPython.core import debugger, oinspect
46 46 from IPython.core import page
47 47 from IPython.core.error import UsageError, StdinNotImplementedError, TryNext
48 48 from IPython.core.macro import Macro
49 49 from IPython.core.magic import (Bunch, Magics, compress_dhist,
50 50 on_off, needs_local_scope,
51 51 register_magics, line_magic, cell_magic)
52 52 from IPython.testing.skipdoctest import skip_doctest
53 53 from IPython.utils import openpy
54 54 from IPython.utils import py3compat
55 55 from IPython.utils.encoding import DEFAULT_ENCODING
56 56 from IPython.utils.io import file_read, nlprint
57 57 from IPython.utils.ipstruct import Struct
58 58 from IPython.utils.module_paths import find_mod
59 59 from IPython.utils.path import get_py_filename, unquote_filename
60 60 from IPython.utils.process import abbrev_cwd
61 61 from IPython.utils.terminal import set_term_title
62 62 from IPython.utils.timing import clock, clock2
63 63 from IPython.utils.warn import warn, error
64 64
65 65 #-----------------------------------------------------------------------------
66 66 # Magic implementation classes
67 67 #-----------------------------------------------------------------------------
68 @register_magics
69 class NamespaceMagics(Magics):
70 """Magics to manage various aspects of the user's namespace.
71
72 These include listing variables, introspecting into them, etc.
73 """
74
75 @line_magic
76 def pinfo(self, parameter_s='', namespaces=None):
77 """Provide detailed information about an object.
78
79 '%pinfo object' is just a synonym for object? or ?object."""
80
81 #print 'pinfo par: <%s>' % parameter_s # dbg
82
83
84 # detail_level: 0 -> obj? , 1 -> obj??
85 detail_level = 0
86 # We need to detect if we got called as 'pinfo pinfo foo', which can
87 # happen if the user types 'pinfo foo?' at the cmd line.
88 pinfo,qmark1,oname,qmark2 = \
89 re.match('(pinfo )?(\?*)(.*?)(\??$)',parameter_s).groups()
90 if pinfo or qmark1 or qmark2:
91 detail_level = 1
92 if "*" in oname:
93 self.psearch(oname)
94 else:
95 self.shell._inspect('pinfo', oname, detail_level=detail_level,
96 namespaces=namespaces)
97
98 @line_magic
99 def pinfo2(self, parameter_s='', namespaces=None):
100 """Provide extra detailed information about an object.
101
102 '%pinfo2 object' is just a synonym for object?? or ??object."""
103 self.shell._inspect('pinfo', parameter_s, detail_level=1,
104 namespaces=namespaces)
105
106 @skip_doctest
107 @line_magic
108 def pdef(self, parameter_s='', namespaces=None):
109 """Print the definition header for any callable object.
110
111 If the object is a class, print the constructor information.
112
113 Examples
114 --------
115 ::
116
117 In [3]: %pdef urllib.urlopen
118 urllib.urlopen(url, data=None, proxies=None)
119 """
120 self._inspect('pdef',parameter_s, namespaces)
121
122 @line_magic
123 def pdoc(self, parameter_s='', namespaces=None):
124 """Print the docstring for an object.
125
126 If the given object is a class, it will print both the class and the
127 constructor docstrings."""
128 self._inspect('pdoc',parameter_s, namespaces)
129
130 @line_magic
131 def psource(self, parameter_s='', namespaces=None):
132 """Print (or run through pager) the source code for an object."""
133 self._inspect('psource',parameter_s, namespaces)
134
135 @line_magic
136 def pfile(self, parameter_s=''):
137 """Print (or run through pager) the file where an object is defined.
138
139 The file opens at the line where the object definition begins. IPython
140 will honor the environment variable PAGER if set, and otherwise will
141 do its best to print the file in a convenient form.
142
143 If the given argument is not an object currently defined, IPython will
144 try to interpret it as a filename (automatically adding a .py extension
145 if needed). You can thus use %pfile as a syntax highlighting code
146 viewer."""
147
148 # first interpret argument as an object name
149 out = self._inspect('pfile',parameter_s)
150 # if not, try the input as a filename
151 if out == 'not found':
152 try:
153 filename = get_py_filename(parameter_s)
154 except IOError,msg:
155 print msg
156 return
157 page.page(self.shell.inspector.format(open(filename).read()))
158
159 @line_magic
160 def psearch(self, parameter_s=''):
161 """Search for object in namespaces by wildcard.
162
163 %psearch [options] PATTERN [OBJECT TYPE]
164
165 Note: ? can be used as a synonym for %psearch, at the beginning or at
166 the end: both a*? and ?a* are equivalent to '%psearch a*'. Still, the
167 rest of the command line must be unchanged (options come first), so
168 for example the following forms are equivalent
169
170 %psearch -i a* function
171 -i a* function?
172 ?-i a* function
173
174 Arguments:
175
176 PATTERN
177
178 where PATTERN is a string containing * as a wildcard similar to its
179 use in a shell. The pattern is matched in all namespaces on the
180 search path. By default objects starting with a single _ are not
181 matched, many IPython generated objects have a single
182 underscore. The default is case insensitive matching. Matching is
183 also done on the attributes of objects and not only on the objects
184 in a module.
185
186 [OBJECT TYPE]
187
188 Is the name of a python type from the types module. The name is
189 given in lowercase without the ending type, ex. StringType is
190 written string. By adding a type here only objects matching the
191 given type are matched. Using all here makes the pattern match all
192 types (this is the default).
193
194 Options:
195
196 -a: makes the pattern match even objects whose names start with a
197 single underscore. These names are normally omitted from the
198 search.
199
200 -i/-c: make the pattern case insensitive/sensitive. If neither of
201 these options are given, the default is read from your configuration
202 file, with the option ``InteractiveShell.wildcards_case_sensitive``.
203 If this option is not specified in your configuration file, IPython's
204 internal default is to do a case sensitive search.
205
206 -e/-s NAMESPACE: exclude/search a given namespace. The pattern you
207 specify can be searched in any of the following namespaces:
208 'builtin', 'user', 'user_global','internal', 'alias', where
209 'builtin' and 'user' are the search defaults. Note that you should
210 not use quotes when specifying namespaces.
211
212 'Builtin' contains the python module builtin, 'user' contains all
213 user data, 'alias' only contain the shell aliases and no python
214 objects, 'internal' contains objects used by IPython. The
215 'user_global' namespace is only used by embedded IPython instances,
216 and it contains module-level globals. You can add namespaces to the
217 search with -s or exclude them with -e (these options can be given
218 more than once).
219
220 Examples
221 --------
222 ::
223
224 %psearch a* -> objects beginning with an a
225 %psearch -e builtin a* -> objects NOT in the builtin space starting in a
226 %psearch a* function -> all functions beginning with an a
227 %psearch re.e* -> objects beginning with an e in module re
228 %psearch r*.e* -> objects that start with e in modules starting in r
229 %psearch r*.* string -> all strings in modules beginning with r
230
231 Case sensitive search::
232
233 %psearch -c a* list all object beginning with lower case a
234
235 Show objects beginning with a single _::
236
237 %psearch -a _* list objects beginning with a single underscore
238 """
239 try:
240 parameter_s.encode('ascii')
241 except UnicodeEncodeError:
242 print 'Python identifiers can only contain ascii characters.'
243 return
244
245 # default namespaces to be searched
246 def_search = ['user_local', 'user_global', 'builtin']
247
248 # Process options/args
249 opts,args = self.parse_options(parameter_s,'cias:e:',list_all=True)
250 opt = opts.get
251 shell = self.shell
252 psearch = shell.inspector.psearch
253
254 # select case options
255 if opts.has_key('i'):
256 ignore_case = True
257 elif opts.has_key('c'):
258 ignore_case = False
259 else:
260 ignore_case = not shell.wildcards_case_sensitive
261
262 # Build list of namespaces to search from user options
263 def_search.extend(opt('s',[]))
264 ns_exclude = ns_exclude=opt('e',[])
265 ns_search = [nm for nm in def_search if nm not in ns_exclude]
266
267 # Call the actual search
268 try:
269 psearch(args,shell.ns_table,ns_search,
270 show_all=opt('a'),ignore_case=ignore_case)
271 except:
272 shell.showtraceback()
273
274 @skip_doctest
275 @line_magic
276 def who_ls(self, parameter_s=''):
277 """Return a sorted list of all interactive variables.
278
279 If arguments are given, only variables of types matching these
280 arguments are returned.
281
282 Examples
283 --------
284
285 Define two variables and list them with who_ls::
286
287 In [1]: alpha = 123
288
289 In [2]: beta = 'test'
290
291 In [3]: %who_ls
292 Out[3]: ['alpha', 'beta']
293
294 In [4]: %who_ls int
295 Out[4]: ['alpha']
296
297 In [5]: %who_ls str
298 Out[5]: ['beta']
299 """
300
301 user_ns = self.shell.user_ns
302 user_ns_hidden = self.shell.user_ns_hidden
303 out = [ i for i in user_ns
304 if not i.startswith('_') \
305 and not i in user_ns_hidden ]
306
307 typelist = parameter_s.split()
308 if typelist:
309 typeset = set(typelist)
310 out = [i for i in out if type(user_ns[i]).__name__ in typeset]
311
312 out.sort()
313 return out
314
315 @skip_doctest
316 @line_magic
317 def who(self, parameter_s=''):
318 """Print all interactive variables, with some minimal formatting.
319
320 If any arguments are given, only variables whose type matches one of
321 these are printed. For example::
322
323 %who function str
324
325 will only list functions and strings, excluding all other types of
326 variables. To find the proper type names, simply use type(var) at a
327 command line to see how python prints type names. For example:
328
329 ::
330
331 In [1]: type('hello')\\
332 Out[1]: <type 'str'>
333
334 indicates that the type name for strings is 'str'.
335
336 ``%who`` always excludes executed names loaded through your configuration
337 file and things which are internal to IPython.
338
339 This is deliberate, as typically you may load many modules and the
340 purpose of %who is to show you only what you've manually defined.
341
342 Examples
343 --------
344
345 Define two variables and list them with who::
346
347 In [1]: alpha = 123
348
349 In [2]: beta = 'test'
350
351 In [3]: %who
352 alpha beta
353
354 In [4]: %who int
355 alpha
356
357 In [5]: %who str
358 beta
359 """
360
361 varlist = self.who_ls(parameter_s)
362 if not varlist:
363 if parameter_s:
364 print 'No variables match your requested type.'
365 else:
366 print 'Interactive namespace is empty.'
367 return
368
369 # if we have variables, move on...
370 count = 0
371 for i in varlist:
372 print i+'\t',
373 count += 1
374 if count > 8:
375 count = 0
376 print
377 print
378
379 @skip_doctest
380 @line_magic
381 def whos(self, parameter_s=''):
382 """Like %who, but gives some extra information about each variable.
383
384 The same type filtering of %who can be applied here.
385
386 For all variables, the type is printed. Additionally it prints:
387
388 - For {},[],(): their length.
389
390 - For numpy arrays, a summary with shape, number of
391 elements, typecode and size in memory.
392
393 - Everything else: a string representation, snipping their middle if
394 too long.
395
396 Examples
397 --------
398
399 Define two variables and list them with whos::
400
401 In [1]: alpha = 123
402
403 In [2]: beta = 'test'
404
405 In [3]: %whos
406 Variable Type Data/Info
407 --------------------------------
408 alpha int 123
409 beta str test
410 """
411
412 varnames = self.who_ls(parameter_s)
413 if not varnames:
414 if parameter_s:
415 print 'No variables match your requested type.'
416 else:
417 print 'Interactive namespace is empty.'
418 return
419
420 # if we have variables, move on...
421
422 # for these types, show len() instead of data:
423 seq_types = ['dict', 'list', 'tuple']
424
425 # for numpy arrays, display summary info
426 ndarray_type = None
427 if 'numpy' in sys.modules:
428 try:
429 from numpy import ndarray
430 except ImportError:
431 pass
432 else:
433 ndarray_type = ndarray.__name__
434
435 # Find all variable names and types so we can figure out column sizes
436 def get_vars(i):
437 return self.shell.user_ns[i]
438
439 # some types are well known and can be shorter
440 abbrevs = {'IPython.core.macro.Macro' : 'Macro'}
441 def type_name(v):
442 tn = type(v).__name__
443 return abbrevs.get(tn,tn)
444
445 varlist = map(get_vars,varnames)
446
447 typelist = []
448 for vv in varlist:
449 tt = type_name(vv)
450
451 if tt=='instance':
452 typelist.append( abbrevs.get(str(vv.__class__),
453 str(vv.__class__)))
454 else:
455 typelist.append(tt)
456
457 # column labels and # of spaces as separator
458 varlabel = 'Variable'
459 typelabel = 'Type'
460 datalabel = 'Data/Info'
461 colsep = 3
462 # variable format strings
463 vformat = "{0:<{varwidth}}{1:<{typewidth}}"
464 aformat = "%s: %s elems, type `%s`, %s bytes"
465 # find the size of the columns to format the output nicely
466 varwidth = max(max(map(len,varnames)), len(varlabel)) + colsep
467 typewidth = max(max(map(len,typelist)), len(typelabel)) + colsep
468 # table header
469 print varlabel.ljust(varwidth) + typelabel.ljust(typewidth) + \
470 ' '+datalabel+'\n' + '-'*(varwidth+typewidth+len(datalabel)+1)
471 # and the table itself
472 kb = 1024
473 Mb = 1048576 # kb**2
474 for vname,var,vtype in zip(varnames,varlist,typelist):
475 print vformat.format(vname, vtype, varwidth=varwidth, typewidth=typewidth),
476 if vtype in seq_types:
477 print "n="+str(len(var))
478 elif vtype == ndarray_type:
479 vshape = str(var.shape).replace(',','').replace(' ','x')[1:-1]
480 if vtype==ndarray_type:
481 # numpy
482 vsize = var.size
483 vbytes = vsize*var.itemsize
484 vdtype = var.dtype
485
486 if vbytes < 100000:
487 print aformat % (vshape,vsize,vdtype,vbytes)
488 else:
489 print aformat % (vshape,vsize,vdtype,vbytes),
490 if vbytes < Mb:
491 print '(%s kb)' % (vbytes/kb,)
492 else:
493 print '(%s Mb)' % (vbytes/Mb,)
494 else:
495 try:
496 vstr = str(var)
497 except UnicodeEncodeError:
498 vstr = unicode(var).encode(DEFAULT_ENCODING,
499 'backslashreplace')
500 except:
501 vstr = "<object with id %d (str() failed)>" % id(var)
502 vstr = vstr.replace('\n','\\n')
503 if len(vstr) < 50:
504 print vstr
505 else:
506 print vstr[:25] + "<...>" + vstr[-25:]
507
508 @line_magic
509 def reset(self, parameter_s=''):
510 """Resets the namespace by removing all names defined by the user, if
511 called without arguments, or by removing some types of objects, such
512 as everything currently in IPython's In[] and Out[] containers (see
513 the parameters for details).
514
515 Parameters
516 ----------
517 -f : force reset without asking for confirmation.
518
519 -s : 'Soft' reset: Only clears your namespace, leaving history intact.
520 References to objects may be kept. By default (without this option),
521 we do a 'hard' reset, giving you a new session and removing all
522 references to objects from the current session.
523
524 in : reset input history
525
526 out : reset output history
527
528 dhist : reset directory history
529
530 array : reset only variables that are NumPy arrays
531
532 See Also
533 --------
534 magic_reset_selective : invoked as ``%reset_selective``
535
536 Examples
537 --------
538 ::
539
540 In [6]: a = 1
541
542 In [7]: a
543 Out[7]: 1
544
545 In [8]: 'a' in _ip.user_ns
546 Out[8]: True
547
548 In [9]: %reset -f
549
550 In [1]: 'a' in _ip.user_ns
551 Out[1]: False
552
553 In [2]: %reset -f in
554 Flushing input history
555
556 In [3]: %reset -f dhist in
557 Flushing directory history
558 Flushing input history
559
560 Notes
561 -----
562 Calling this magic from clients that do not implement standard input,
563 such as the ipython notebook interface, will reset the namespace
564 without confirmation.
565 """
566 opts, args = self.parse_options(parameter_s,'sf', mode='list')
567 if 'f' in opts:
568 ans = True
569 else:
570 try:
571 ans = self.shell.ask_yes_no(
572 "Once deleted, variables cannot be recovered. Proceed (y/[n])?",
573 default='n')
574 except StdinNotImplementedError:
575 ans = True
576 if not ans:
577 print 'Nothing done.'
578 return
579
580 if 's' in opts: # Soft reset
581 user_ns = self.shell.user_ns
582 for i in self.who_ls():
583 del(user_ns[i])
584 elif len(args) == 0: # Hard reset
585 self.shell.reset(new_session = False)
586
587 # reset in/out/dhist/array: previously extensinions/clearcmd.py
588 ip = self.shell
589 user_ns = self.shell.user_ns # local lookup, heavily used
590
591 for target in args:
592 target = target.lower() # make matches case insensitive
593 if target == 'out':
594 print "Flushing output cache (%d entries)" % len(user_ns['_oh'])
595 self.shell.displayhook.flush()
596
597 elif target == 'in':
598 print "Flushing input history"
599 pc = self.shell.displayhook.prompt_count + 1
600 for n in range(1, pc):
601 key = '_i'+repr(n)
602 user_ns.pop(key,None)
603 user_ns.update(dict(_i=u'',_ii=u'',_iii=u''))
604 hm = ip.history_manager
605 # don't delete these, as %save and %macro depending on the
606 # length of these lists to be preserved
607 hm.input_hist_parsed[:] = [''] * pc
608 hm.input_hist_raw[:] = [''] * pc
609 # hm has internal machinery for _i,_ii,_iii, clear it out
610 hm._i = hm._ii = hm._iii = hm._i00 = u''
611
612 elif target == 'array':
613 # Support cleaning up numpy arrays
614 try:
615 from numpy import ndarray
616 # This must be done with items and not iteritems because
617 # we're going to modify the dict in-place.
618 for x,val in user_ns.items():
619 if isinstance(val,ndarray):
620 del user_ns[x]
621 except ImportError:
622 print "reset array only works if Numpy is available."
623
624 elif target == 'dhist':
625 print "Flushing directory history"
626 del user_ns['_dh'][:]
627
628 else:
629 print "Don't know how to reset ",
630 print target + ", please run `%reset?` for details"
631
632 gc.collect()
633
634 @line_magic
635 def reset_selective(self, parameter_s=''):
636 """Resets the namespace by removing names defined by the user.
637
638 Input/Output history are left around in case you need them.
639
640 %reset_selective [-f] regex
641
642 No action is taken if regex is not included
643
644 Options
645 -f : force reset without asking for confirmation.
646
647 See Also
648 --------
649 magic_reset : invoked as ``%reset``
650
651 Examples
652 --------
653
654 We first fully reset the namespace so your output looks identical to
655 this example for pedagogical reasons; in practice you do not need a
656 full reset::
657
658 In [1]: %reset -f
659
660 Now, with a clean namespace we can make a few variables and use
661 ``%reset_selective`` to only delete names that match our regexp::
662
663 In [2]: a=1; b=2; c=3; b1m=4; b2m=5; b3m=6; b4m=7; b2s=8
664
665 In [3]: who_ls
666 Out[3]: ['a', 'b', 'b1m', 'b2m', 'b2s', 'b3m', 'b4m', 'c']
667
668 In [4]: %reset_selective -f b[2-3]m
669
670 In [5]: who_ls
671 Out[5]: ['a', 'b', 'b1m', 'b2s', 'b4m', 'c']
672
673 In [6]: %reset_selective -f d
674
675 In [7]: who_ls
676 Out[7]: ['a', 'b', 'b1m', 'b2s', 'b4m', 'c']
677
678 In [8]: %reset_selective -f c
679
680 In [9]: who_ls
681 Out[9]: ['a', 'b', 'b1m', 'b2s', 'b4m']
682
683 In [10]: %reset_selective -f b
684
685 In [11]: who_ls
686 Out[11]: ['a']
687
688 Notes
689 -----
690 Calling this magic from clients that do not implement standard input,
691 such as the ipython notebook interface, will reset the namespace
692 without confirmation.
693 """
694
695 opts, regex = self.parse_options(parameter_s,'f')
696
697 if opts.has_key('f'):
698 ans = True
699 else:
700 try:
701 ans = self.shell.ask_yes_no(
702 "Once deleted, variables cannot be recovered. Proceed (y/[n])? ",
703 default='n')
704 except StdinNotImplementedError:
705 ans = True
706 if not ans:
707 print 'Nothing done.'
708 return
709 user_ns = self.shell.user_ns
710 if not regex:
711 print 'No regex pattern specified. Nothing done.'
712 return
713 else:
714 try:
715 m = re.compile(regex)
716 except TypeError:
717 raise TypeError('regex must be a string or compiled pattern')
718 for i in self.who_ls():
719 if m.search(i):
720 del(user_ns[i])
721
722 @line_magic
723 def xdel(self, parameter_s=''):
724 """Delete a variable, trying to clear it from anywhere that
725 IPython's machinery has references to it. By default, this uses
726 the identity of the named object in the user namespace to remove
727 references held under other names. The object is also removed
728 from the output history.
729
730 Options
731 -n : Delete the specified name from all namespaces, without
732 checking their identity.
733 """
734 opts, varname = self.parse_options(parameter_s,'n')
735 try:
736 self.shell.del_var(varname, ('n' in opts))
737 except (NameError, ValueError) as e:
738 print type(e).__name__ +": "+ str(e)
739
740 68
741 69 @register_magics
742 70 class ExecutionMagics(Magics):
743 71 """Magics related to code execution, debugging, profiling, etc.
744 72
745 73 """
746 74
747 75 def __init__(self, shell):
748 76 super(ExecutionMagics, self).__init__(shell)
749 77 if profile is None:
750 78 self.prun = self.profile_missing_notice
751 79 # Default execution function used to actually run user code.
752 80 self.default_runner = None
753 81
754 82 def profile_missing_notice(self, *args, **kwargs):
755 83 error("""\
756 84 The profile module could not be found. It has been removed from the standard
757 85 python packages because of its non-free license. To use profiling, install the
758 86 python-profiler package from non-free.""")
759 87
760 88 @skip_doctest
761 89 @line_magic
762 90 def prun(self, parameter_s='',user_mode=1,
763 91 opts=None,arg_lst=None,prog_ns=None):
764 92
765 93 """Run a statement through the python code profiler.
766 94
767 95 Usage:
768 96 %prun [options] statement
769 97
770 98 The given statement (which doesn't require quote marks) is run via the
771 99 python profiler in a manner similar to the profile.run() function.
772 100 Namespaces are internally managed to work correctly; profile.run
773 101 cannot be used in IPython because it makes certain assumptions about
774 102 namespaces which do not hold under IPython.
775 103
776 104 Options:
777 105
778 106 -l <limit>: you can place restrictions on what or how much of the
779 107 profile gets printed. The limit value can be:
780 108
781 109 * A string: only information for function names containing this string
782 110 is printed.
783 111
784 112 * An integer: only these many lines are printed.
785 113
786 114 * A float (between 0 and 1): this fraction of the report is printed
787 115 (for example, use a limit of 0.4 to see the topmost 40% only).
788 116
789 117 You can combine several limits with repeated use of the option. For
790 118 example, '-l __init__ -l 5' will print only the topmost 5 lines of
791 119 information about class constructors.
792 120
793 121 -r: return the pstats.Stats object generated by the profiling. This
794 122 object has all the information about the profile in it, and you can
795 123 later use it for further analysis or in other functions.
796 124
797 125 -s <key>: sort profile by given key. You can provide more than one key
798 126 by using the option several times: '-s key1 -s key2 -s key3...'. The
799 127 default sorting key is 'time'.
800 128
801 129 The following is copied verbatim from the profile documentation
802 130 referenced below:
803 131
804 132 When more than one key is provided, additional keys are used as
805 133 secondary criteria when the there is equality in all keys selected
806 134 before them.
807 135
808 136 Abbreviations can be used for any key names, as long as the
809 137 abbreviation is unambiguous. The following are the keys currently
810 138 defined:
811 139
812 140 Valid Arg Meaning
813 141 "calls" call count
814 142 "cumulative" cumulative time
815 143 "file" file name
816 144 "module" file name
817 145 "pcalls" primitive call count
818 146 "line" line number
819 147 "name" function name
820 148 "nfl" name/file/line
821 149 "stdname" standard name
822 150 "time" internal time
823 151
824 152 Note that all sorts on statistics are in descending order (placing
825 153 most time consuming items first), where as name, file, and line number
826 154 searches are in ascending order (i.e., alphabetical). The subtle
827 155 distinction between "nfl" and "stdname" is that the standard name is a
828 156 sort of the name as printed, which means that the embedded line
829 157 numbers get compared in an odd way. For example, lines 3, 20, and 40
830 158 would (if the file names were the same) appear in the string order
831 159 "20" "3" and "40". In contrast, "nfl" does a numeric compare of the
832 160 line numbers. In fact, sort_stats("nfl") is the same as
833 161 sort_stats("name", "file", "line").
834 162
835 163 -T <filename>: save profile results as shown on screen to a text
836 164 file. The profile is still shown on screen.
837 165
838 166 -D <filename>: save (via dump_stats) profile statistics to given
839 167 filename. This data is in a format understood by the pstats module, and
840 168 is generated by a call to the dump_stats() method of profile
841 169 objects. The profile is still shown on screen.
842 170
843 171 -q: suppress output to the pager. Best used with -T and/or -D above.
844 172
845 173 If you want to run complete programs under the profiler's control, use
846 174 '%run -p [prof_opts] filename.py [args to program]' where prof_opts
847 175 contains profiler specific options as described here.
848 176
849 177 You can read the complete documentation for the profile module with::
850 178
851 179 In [1]: import profile; profile.help()
852 180 """
853 181
854 182 opts_def = Struct(D=[''],l=[],s=['time'],T=[''])
855 183
856 184 if user_mode: # regular user call
857 185 opts,arg_str = self.parse_options(parameter_s,'D:l:rs:T:q',
858 186 list_all=1, posix=False)
859 187 namespace = self.shell.user_ns
860 188 else: # called to run a program by %run -p
861 189 try:
862 190 filename = get_py_filename(arg_lst[0])
863 191 except IOError as e:
864 192 try:
865 193 msg = str(e)
866 194 except UnicodeError:
867 195 msg = e.message
868 196 error(msg)
869 197 return
870 198
871 199 arg_str = 'execfile(filename,prog_ns)'
872 200 namespace = {
873 201 'execfile': self.shell.safe_execfile,
874 202 'prog_ns': prog_ns,
875 203 'filename': filename
876 204 }
877 205
878 206 opts.merge(opts_def)
879 207
880 208 prof = profile.Profile()
881 209 try:
882 210 prof = prof.runctx(arg_str,namespace,namespace)
883 211 sys_exit = ''
884 212 except SystemExit:
885 213 sys_exit = """*** SystemExit exception caught in code being profiled."""
886 214
887 215 stats = pstats.Stats(prof).strip_dirs().sort_stats(*opts.s)
888 216
889 217 lims = opts.l
890 218 if lims:
891 219 lims = [] # rebuild lims with ints/floats/strings
892 220 for lim in opts.l:
893 221 try:
894 222 lims.append(int(lim))
895 223 except ValueError:
896 224 try:
897 225 lims.append(float(lim))
898 226 except ValueError:
899 227 lims.append(lim)
900 228
901 229 # Trap output.
902 230 stdout_trap = StringIO()
903 231
904 232 if hasattr(stats,'stream'):
905 233 # In newer versions of python, the stats object has a 'stream'
906 234 # attribute to write into.
907 235 stats.stream = stdout_trap
908 236 stats.print_stats(*lims)
909 237 else:
910 238 # For older versions, we manually redirect stdout during printing
911 239 sys_stdout = sys.stdout
912 240 try:
913 241 sys.stdout = stdout_trap
914 242 stats.print_stats(*lims)
915 243 finally:
916 244 sys.stdout = sys_stdout
917 245
918 246 output = stdout_trap.getvalue()
919 247 output = output.rstrip()
920 248
921 249 if 'q' not in opts:
922 250 page.page(output)
923 251 print sys_exit,
924 252
925 253 dump_file = opts.D[0]
926 254 text_file = opts.T[0]
927 255 if dump_file:
928 256 dump_file = unquote_filename(dump_file)
929 257 prof.dump_stats(dump_file)
930 258 print '\n*** Profile stats marshalled to file',\
931 259 `dump_file`+'.',sys_exit
932 260 if text_file:
933 261 text_file = unquote_filename(text_file)
934 262 pfile = open(text_file,'w')
935 263 pfile.write(output)
936 264 pfile.close()
937 265 print '\n*** Profile printout saved to text file',\
938 266 `text_file`+'.',sys_exit
939 267
940 268 if opts.has_key('r'):
941 269 return stats
942 270 else:
943 271 return None
944 272
945 273 @line_magic
946 274 def pdb(self, parameter_s=''):
947 275 """Control the automatic calling of the pdb interactive debugger.
948 276
949 277 Call as '%pdb on', '%pdb 1', '%pdb off' or '%pdb 0'. If called without
950 278 argument it works as a toggle.
951 279
952 280 When an exception is triggered, IPython can optionally call the
953 281 interactive pdb debugger after the traceback printout. %pdb toggles
954 282 this feature on and off.
955 283
956 284 The initial state of this feature is set in your configuration
957 285 file (the option is ``InteractiveShell.pdb``).
958 286
959 287 If you want to just activate the debugger AFTER an exception has fired,
960 288 without having to type '%pdb on' and rerunning your code, you can use
961 289 the %debug magic."""
962 290
963 291 par = parameter_s.strip().lower()
964 292
965 293 if par:
966 294 try:
967 295 new_pdb = {'off':0,'0':0,'on':1,'1':1}[par]
968 296 except KeyError:
969 297 print ('Incorrect argument. Use on/1, off/0, '
970 298 'or nothing for a toggle.')
971 299 return
972 300 else:
973 301 # toggle
974 302 new_pdb = not self.shell.call_pdb
975 303
976 304 # set on the shell
977 305 self.shell.call_pdb = new_pdb
978 306 print 'Automatic pdb calling has been turned',on_off(new_pdb)
979 307
980 308 @line_magic
981 309 def debug(self, parameter_s=''):
982 310 """Activate the interactive debugger in post-mortem mode.
983 311
984 312 If an exception has just occurred, this lets you inspect its stack
985 313 frames interactively. Note that this will always work only on the last
986 314 traceback that occurred, so you must call this quickly after an
987 315 exception that you wish to inspect has fired, because if another one
988 316 occurs, it clobbers the previous one.
989 317
990 318 If you want IPython to automatically do this on every exception, see
991 319 the %pdb magic for more details.
992 320 """
993 321 self.shell.debugger(force=True)
994 322
995 323 @line_magic
996 324 def tb(self, s):
997 325 """Print the last traceback with the currently active exception mode.
998 326
999 327 See %xmode for changing exception reporting modes."""
1000 328 self.shell.showtraceback()
1001 329
1002 330 @skip_doctest
1003 331 @line_magic
1004 332 def run(self, parameter_s='', runner=None,
1005 333 file_finder=get_py_filename):
1006 334 """Run the named file inside IPython as a program.
1007 335
1008 336 Usage:\\
1009 337 %run [-n -i -t [-N<N>] -d [-b<N>] -p [profile options]] file [args]
1010 338
1011 339 Parameters after the filename are passed as command-line arguments to
1012 340 the program (put in sys.argv). Then, control returns to IPython's
1013 341 prompt.
1014 342
1015 343 This is similar to running at a system prompt:\\
1016 344 $ python file args\\
1017 345 but with the advantage of giving you IPython's tracebacks, and of
1018 346 loading all variables into your interactive namespace for further use
1019 347 (unless -p is used, see below).
1020 348
1021 349 The file is executed in a namespace initially consisting only of
1022 350 __name__=='__main__' and sys.argv constructed as indicated. It thus
1023 351 sees its environment as if it were being run as a stand-alone program
1024 352 (except for sharing global objects such as previously imported
1025 353 modules). But after execution, the IPython interactive namespace gets
1026 354 updated with all variables defined in the program (except for __name__
1027 355 and sys.argv). This allows for very convenient loading of code for
1028 356 interactive work, while giving each program a 'clean sheet' to run in.
1029 357
1030 358 Options:
1031 359
1032 360 -n: __name__ is NOT set to '__main__', but to the running file's name
1033 361 without extension (as python does under import). This allows running
1034 362 scripts and reloading the definitions in them without calling code
1035 363 protected by an ' if __name__ == "__main__" ' clause.
1036 364
1037 365 -i: run the file in IPython's namespace instead of an empty one. This
1038 366 is useful if you are experimenting with code written in a text editor
1039 367 which depends on variables defined interactively.
1040 368
1041 369 -e: ignore sys.exit() calls or SystemExit exceptions in the script
1042 370 being run. This is particularly useful if IPython is being used to
1043 371 run unittests, which always exit with a sys.exit() call. In such
1044 372 cases you are interested in the output of the test results, not in
1045 373 seeing a traceback of the unittest module.
1046 374
1047 375 -t: print timing information at the end of the run. IPython will give
1048 376 you an estimated CPU time consumption for your script, which under
1049 377 Unix uses the resource module to avoid the wraparound problems of
1050 378 time.clock(). Under Unix, an estimate of time spent on system tasks
1051 379 is also given (for Windows platforms this is reported as 0.0).
1052 380
1053 381 If -t is given, an additional -N<N> option can be given, where <N>
1054 382 must be an integer indicating how many times you want the script to
1055 383 run. The final timing report will include total and per run results.
1056 384
1057 385 For example (testing the script uniq_stable.py)::
1058 386
1059 387 In [1]: run -t uniq_stable
1060 388
1061 389 IPython CPU timings (estimated):\\
1062 390 User : 0.19597 s.\\
1063 391 System: 0.0 s.\\
1064 392
1065 393 In [2]: run -t -N5 uniq_stable
1066 394
1067 395 IPython CPU timings (estimated):\\
1068 396 Total runs performed: 5\\
1069 397 Times : Total Per run\\
1070 398 User : 0.910862 s, 0.1821724 s.\\
1071 399 System: 0.0 s, 0.0 s.
1072 400
1073 401 -d: run your program under the control of pdb, the Python debugger.
1074 402 This allows you to execute your program step by step, watch variables,
1075 403 etc. Internally, what IPython does is similar to calling:
1076 404
1077 405 pdb.run('execfile("YOURFILENAME")')
1078 406
1079 407 with a breakpoint set on line 1 of your file. You can change the line
1080 408 number for this automatic breakpoint to be <N> by using the -bN option
1081 409 (where N must be an integer). For example::
1082 410
1083 411 %run -d -b40 myscript
1084 412
1085 413 will set the first breakpoint at line 40 in myscript.py. Note that
1086 414 the first breakpoint must be set on a line which actually does
1087 415 something (not a comment or docstring) for it to stop execution.
1088 416
1089 417 When the pdb debugger starts, you will see a (Pdb) prompt. You must
1090 418 first enter 'c' (without quotes) to start execution up to the first
1091 419 breakpoint.
1092 420
1093 421 Entering 'help' gives information about the use of the debugger. You
1094 422 can easily see pdb's full documentation with "import pdb;pdb.help()"
1095 423 at a prompt.
1096 424
1097 425 -p: run program under the control of the Python profiler module (which
1098 426 prints a detailed report of execution times, function calls, etc).
1099 427
1100 428 You can pass other options after -p which affect the behavior of the
1101 429 profiler itself. See the docs for %prun for details.
1102 430
1103 431 In this mode, the program's variables do NOT propagate back to the
1104 432 IPython interactive namespace (because they remain in the namespace
1105 433 where the profiler executes them).
1106 434
1107 435 Internally this triggers a call to %prun, see its documentation for
1108 436 details on the options available specifically for profiling.
1109 437
1110 438 There is one special usage for which the text above doesn't apply:
1111 439 if the filename ends with .ipy, the file is run as ipython script,
1112 440 just as if the commands were written on IPython prompt.
1113 441
1114 442 -m: specify module name to load instead of script path. Similar to
1115 443 the -m option for the python interpreter. Use this option last if you
1116 444 want to combine with other %run options. Unlike the python interpreter
1117 445 only source modules are allowed no .pyc or .pyo files.
1118 446 For example::
1119 447
1120 448 %run -m example
1121 449
1122 450 will run the example module.
1123 451
1124 452 """
1125 453
1126 454 # get arguments and set sys.argv for program to be run.
1127 455 opts, arg_lst = self.parse_options(parameter_s, 'nidtN:b:pD:l:rs:T:em:',
1128 456 mode='list', list_all=1)
1129 457 if "m" in opts:
1130 458 modulename = opts["m"][0]
1131 459 modpath = find_mod(modulename)
1132 460 if modpath is None:
1133 461 warn('%r is not a valid modulename on sys.path'%modulename)
1134 462 return
1135 463 arg_lst = [modpath] + arg_lst
1136 464 try:
1137 465 filename = file_finder(arg_lst[0])
1138 466 except IndexError:
1139 467 warn('you must provide at least a filename.')
1140 468 print '\n%run:\n', oinspect.getdoc(self.run)
1141 469 return
1142 470 except IOError as e:
1143 471 try:
1144 472 msg = str(e)
1145 473 except UnicodeError:
1146 474 msg = e.message
1147 475 error(msg)
1148 476 return
1149 477
1150 478 if filename.lower().endswith('.ipy'):
1151 479 self.shell.safe_execfile_ipy(filename)
1152 480 return
1153 481
1154 482 # Control the response to exit() calls made by the script being run
1155 483 exit_ignore = 'e' in opts
1156 484
1157 485 # Make sure that the running script gets a proper sys.argv as if it
1158 486 # were run from a system shell.
1159 487 save_argv = sys.argv # save it for later restoring
1160 488
1161 489 # simulate shell expansion on arguments, at least tilde expansion
1162 490 args = [ os.path.expanduser(a) for a in arg_lst[1:] ]
1163 491
1164 492 sys.argv = [filename] + args # put in the proper filename
1165 493 # protect sys.argv from potential unicode strings on Python 2:
1166 494 if not py3compat.PY3:
1167 495 sys.argv = [ py3compat.cast_bytes(a) for a in sys.argv ]
1168 496
1169 497 if 'i' in opts:
1170 498 # Run in user's interactive namespace
1171 499 prog_ns = self.shell.user_ns
1172 500 __name__save = self.shell.user_ns['__name__']
1173 501 prog_ns['__name__'] = '__main__'
1174 502 main_mod = self.shell.new_main_mod(prog_ns)
1175 503 else:
1176 504 # Run in a fresh, empty namespace
1177 505 if 'n' in opts:
1178 506 name = os.path.splitext(os.path.basename(filename))[0]
1179 507 else:
1180 508 name = '__main__'
1181 509
1182 510 main_mod = self.shell.new_main_mod()
1183 511 prog_ns = main_mod.__dict__
1184 512 prog_ns['__name__'] = name
1185 513
1186 514 # Since '%run foo' emulates 'python foo.py' at the cmd line, we must
1187 515 # set the __file__ global in the script's namespace
1188 516 prog_ns['__file__'] = filename
1189 517
1190 518 # pickle fix. See interactiveshell for an explanation. But we need to
1191 519 # make sure that, if we overwrite __main__, we replace it at the end
1192 520 main_mod_name = prog_ns['__name__']
1193 521
1194 522 if main_mod_name == '__main__':
1195 523 restore_main = sys.modules['__main__']
1196 524 else:
1197 525 restore_main = False
1198 526
1199 527 # This needs to be undone at the end to prevent holding references to
1200 528 # every single object ever created.
1201 529 sys.modules[main_mod_name] = main_mod
1202 530
1203 531 try:
1204 532 stats = None
1205 533 with self.shell.readline_no_record:
1206 534 if 'p' in opts:
1207 535 stats = self.prun('', 0, opts, arg_lst, prog_ns)
1208 536 else:
1209 537 if 'd' in opts:
1210 538 deb = debugger.Pdb(self.shell.colors)
1211 539 # reset Breakpoint state, which is moronically kept
1212 540 # in a class
1213 541 bdb.Breakpoint.next = 1
1214 542 bdb.Breakpoint.bplist = {}
1215 543 bdb.Breakpoint.bpbynumber = [None]
1216 544 # Set an initial breakpoint to stop execution
1217 545 maxtries = 10
1218 546 bp = int(opts.get('b', [1])[0])
1219 547 checkline = deb.checkline(filename, bp)
1220 548 if not checkline:
1221 549 for bp in range(bp + 1, bp + maxtries + 1):
1222 550 if deb.checkline(filename, bp):
1223 551 break
1224 552 else:
1225 553 msg = ("\nI failed to find a valid line to set "
1226 554 "a breakpoint\n"
1227 555 "after trying up to line: %s.\n"
1228 556 "Please set a valid breakpoint manually "
1229 557 "with the -b option." % bp)
1230 558 error(msg)
1231 559 return
1232 560 # if we find a good linenumber, set the breakpoint
1233 561 deb.do_break('%s:%s' % (filename, bp))
1234 562 # Start file run
1235 563 print "NOTE: Enter 'c' at the",
1236 564 print "%s prompt to start your script." % deb.prompt
1237 565 ns = {'execfile': py3compat.execfile, 'prog_ns': prog_ns}
1238 566 try:
1239 567 deb.run('execfile("%s", prog_ns)' % filename, ns)
1240 568
1241 569 except:
1242 570 etype, value, tb = sys.exc_info()
1243 571 # Skip three frames in the traceback: the %run one,
1244 572 # one inside bdb.py, and the command-line typed by the
1245 573 # user (run by exec in pdb itself).
1246 574 self.shell.InteractiveTB(etype, value, tb, tb_offset=3)
1247 575 else:
1248 576 if runner is None:
1249 577 runner = self.default_runner
1250 578 if runner is None:
1251 579 runner = self.shell.safe_execfile
1252 580 if 't' in opts:
1253 581 # timed execution
1254 582 try:
1255 583 nruns = int(opts['N'][0])
1256 584 if nruns < 1:
1257 585 error('Number of runs must be >=1')
1258 586 return
1259 587 except (KeyError):
1260 588 nruns = 1
1261 589 twall0 = time.time()
1262 590 if nruns == 1:
1263 591 t0 = clock2()
1264 592 runner(filename, prog_ns, prog_ns,
1265 593 exit_ignore=exit_ignore)
1266 594 t1 = clock2()
1267 595 t_usr = t1[0] - t0[0]
1268 596 t_sys = t1[1] - t0[1]
1269 597 print "\nIPython CPU timings (estimated):"
1270 598 print " User : %10.2f s." % t_usr
1271 599 print " System : %10.2f s." % t_sys
1272 600 else:
1273 601 runs = range(nruns)
1274 602 t0 = clock2()
1275 603 for nr in runs:
1276 604 runner(filename, prog_ns, prog_ns,
1277 605 exit_ignore=exit_ignore)
1278 606 t1 = clock2()
1279 607 t_usr = t1[0] - t0[0]
1280 608 t_sys = t1[1] - t0[1]
1281 609 print "\nIPython CPU timings (estimated):"
1282 610 print "Total runs performed:", nruns
1283 611 print " Times : %10.2f %10.2f" % ('Total', 'Per run')
1284 612 print " User : %10.2f s, %10.2f s." % (t_usr, t_usr / nruns)
1285 613 print " System : %10.2f s, %10.2f s." % (t_sys, t_sys / nruns)
1286 614 twall1 = time.time()
1287 615 print "Wall time: %10.2f s." % (twall1 - twall0)
1288 616
1289 617 else:
1290 618 # regular execution
1291 619 runner(filename, prog_ns, prog_ns, exit_ignore=exit_ignore)
1292 620
1293 621 if 'i' in opts:
1294 622 self.shell.user_ns['__name__'] = __name__save
1295 623 else:
1296 624 # The shell MUST hold a reference to prog_ns so after %run
1297 625 # exits, the python deletion mechanism doesn't zero it out
1298 626 # (leaving dangling references).
1299 627 self.shell.cache_main_mod(prog_ns, filename)
1300 628 # update IPython interactive namespace
1301 629
1302 630 # Some forms of read errors on the file may mean the
1303 631 # __name__ key was never set; using pop we don't have to
1304 632 # worry about a possible KeyError.
1305 633 prog_ns.pop('__name__', None)
1306 634
1307 635 self.shell.user_ns.update(prog_ns)
1308 636 finally:
1309 637 # It's a bit of a mystery why, but __builtins__ can change from
1310 638 # being a module to becoming a dict missing some key data after
1311 639 # %run. As best I can see, this is NOT something IPython is doing
1312 640 # at all, and similar problems have been reported before:
1313 641 # http://coding.derkeiler.com/Archive/Python/comp.lang.python/2004-10/0188.html
1314 642 # Since this seems to be done by the interpreter itself, the best
1315 643 # we can do is to at least restore __builtins__ for the user on
1316 644 # exit.
1317 645 self.shell.user_ns['__builtins__'] = builtin_mod
1318 646
1319 647 # Ensure key global structures are restored
1320 648 sys.argv = save_argv
1321 649 if restore_main:
1322 650 sys.modules['__main__'] = restore_main
1323 651 else:
1324 652 # Remove from sys.modules the reference to main_mod we'd
1325 653 # added. Otherwise it will trap references to objects
1326 654 # contained therein.
1327 655 del sys.modules[main_mod_name]
1328 656
1329 657 return stats
1330 658
1331 659 @skip_doctest
1332 660 @line_magic
1333 661 def timeit(self, parameter_s=''):
1334 662 """Time execution of a Python statement or expression
1335 663
1336 664 Usage:\\
1337 665 %timeit [-n<N> -r<R> [-t|-c]] statement
1338 666
1339 667 Time execution of a Python statement or expression using the timeit
1340 668 module.
1341 669
1342 670 Options:
1343 671 -n<N>: execute the given statement <N> times in a loop. If this value
1344 672 is not given, a fitting value is chosen.
1345 673
1346 674 -r<R>: repeat the loop iteration <R> times and take the best result.
1347 675 Default: 3
1348 676
1349 677 -t: use time.time to measure the time, which is the default on Unix.
1350 678 This function measures wall time.
1351 679
1352 680 -c: use time.clock to measure the time, which is the default on
1353 681 Windows and measures wall time. On Unix, resource.getrusage is used
1354 682 instead and returns the CPU user time.
1355 683
1356 684 -p<P>: use a precision of <P> digits to display the timing result.
1357 685 Default: 3
1358 686
1359 687
1360 688 Examples
1361 689 --------
1362 690 ::
1363 691
1364 692 In [1]: %timeit pass
1365 693 10000000 loops, best of 3: 53.3 ns per loop
1366 694
1367 695 In [2]: u = None
1368 696
1369 697 In [3]: %timeit u is None
1370 698 10000000 loops, best of 3: 184 ns per loop
1371 699
1372 700 In [4]: %timeit -r 4 u == None
1373 701 1000000 loops, best of 4: 242 ns per loop
1374 702
1375 703 In [5]: import time
1376 704
1377 705 In [6]: %timeit -n1 time.sleep(2)
1378 706 1 loops, best of 3: 2 s per loop
1379 707
1380 708
1381 709 The times reported by %timeit will be slightly higher than those
1382 710 reported by the timeit.py script when variables are accessed. This is
1383 711 due to the fact that %timeit executes the statement in the namespace
1384 712 of the shell, compared with timeit.py, which uses a single setup
1385 713 statement to import function or create variables. Generally, the bias
1386 714 does not matter as long as results from timeit.py are not mixed with
1387 715 those from %timeit."""
1388 716
1389 717 import timeit
1390 718 import math
1391 719
1392 720 # XXX: Unfortunately the unicode 'micro' symbol can cause problems in
1393 721 # certain terminals. Until we figure out a robust way of
1394 722 # auto-detecting if the terminal can deal with it, use plain 'us' for
1395 723 # microseconds. I am really NOT happy about disabling the proper
1396 724 # 'micro' prefix, but crashing is worse... If anyone knows what the
1397 725 # right solution for this is, I'm all ears...
1398 726 #
1399 727 # Note: using
1400 728 #
1401 729 # s = u'\xb5'
1402 730 # s.encode(sys.getdefaultencoding())
1403 731 #
1404 732 # is not sufficient, as I've seen terminals where that fails but
1405 733 # print s
1406 734 #
1407 735 # succeeds
1408 736 #
1409 737 # See bug: https://bugs.launchpad.net/ipython/+bug/348466
1410 738
1411 739 #units = [u"s", u"ms",u'\xb5',"ns"]
1412 740 units = [u"s", u"ms",u'us',"ns"]
1413 741
1414 742 scaling = [1, 1e3, 1e6, 1e9]
1415 743
1416 744 opts, stmt = self.parse_options(parameter_s,'n:r:tcp:',
1417 745 posix=False, strict=False)
1418 746 if stmt == "":
1419 747 return
1420 748 timefunc = timeit.default_timer
1421 749 number = int(getattr(opts, "n", 0))
1422 750 repeat = int(getattr(opts, "r", timeit.default_repeat))
1423 751 precision = int(getattr(opts, "p", 3))
1424 752 if hasattr(opts, "t"):
1425 753 timefunc = time.time
1426 754 if hasattr(opts, "c"):
1427 755 timefunc = clock
1428 756
1429 757 timer = timeit.Timer(timer=timefunc)
1430 758 # this code has tight coupling to the inner workings of timeit.Timer,
1431 759 # but is there a better way to achieve that the code stmt has access
1432 760 # to the shell namespace?
1433 761
1434 762 src = timeit.template % {'stmt': timeit.reindent(stmt, 8),
1435 763 'setup': "pass"}
1436 764 # Track compilation time so it can be reported if too long
1437 765 # Minimum time above which compilation time will be reported
1438 766 tc_min = 0.1
1439 767
1440 768 t0 = clock()
1441 769 code = compile(src, "<magic-timeit>", "exec")
1442 770 tc = clock()-t0
1443 771
1444 772 ns = {}
1445 773 exec code in self.shell.user_ns, ns
1446 774 timer.inner = ns["inner"]
1447 775
1448 776 if number == 0:
1449 777 # determine number so that 0.2 <= total time < 2.0
1450 778 number = 1
1451 779 for i in range(1, 10):
1452 780 if timer.timeit(number) >= 0.2:
1453 781 break
1454 782 number *= 10
1455 783
1456 784 best = min(timer.repeat(repeat, number)) / number
1457 785
1458 786 if best > 0.0 and best < 1000.0:
1459 787 order = min(-int(math.floor(math.log10(best)) // 3), 3)
1460 788 elif best >= 1000.0:
1461 789 order = 0
1462 790 else:
1463 791 order = 3
1464 792 print u"%d loops, best of %d: %.*g %s per loop" % (number, repeat,
1465 793 precision,
1466 794 best * scaling[order],
1467 795 units[order])
1468 796 if tc > tc_min:
1469 797 print "Compiler time: %.2f s" % tc
1470 798
1471 799 @skip_doctest
1472 800 @needs_local_scope
1473 801 @line_magic
1474 802 def time(self,parameter_s, user_locals):
1475 803 """Time execution of a Python statement or expression.
1476 804
1477 805 The CPU and wall clock times are printed, and the value of the
1478 806 expression (if any) is returned. Note that under Win32, system time
1479 807 is always reported as 0, since it can not be measured.
1480 808
1481 809 This function provides very basic timing functionality. In Python
1482 810 2.3, the timeit module offers more control and sophistication, so this
1483 811 could be rewritten to use it (patches welcome).
1484 812
1485 813 Examples
1486 814 --------
1487 815 ::
1488 816
1489 817 In [1]: time 2**128
1490 818 CPU times: user 0.00 s, sys: 0.00 s, total: 0.00 s
1491 819 Wall time: 0.00
1492 820 Out[1]: 340282366920938463463374607431768211456L
1493 821
1494 822 In [2]: n = 1000000
1495 823
1496 824 In [3]: time sum(range(n))
1497 825 CPU times: user 1.20 s, sys: 0.05 s, total: 1.25 s
1498 826 Wall time: 1.37
1499 827 Out[3]: 499999500000L
1500 828
1501 829 In [4]: time print 'hello world'
1502 830 hello world
1503 831 CPU times: user 0.00 s, sys: 0.00 s, total: 0.00 s
1504 832 Wall time: 0.00
1505 833
1506 834 Note that the time needed by Python to compile the given expression
1507 835 will be reported if it is more than 0.1s. In this example, the
1508 836 actual exponentiation is done by Python at compilation time, so while
1509 837 the expression can take a noticeable amount of time to compute, that
1510 838 time is purely due to the compilation:
1511 839
1512 840 In [5]: time 3**9999;
1513 841 CPU times: user 0.00 s, sys: 0.00 s, total: 0.00 s
1514 842 Wall time: 0.00 s
1515 843
1516 844 In [6]: time 3**999999;
1517 845 CPU times: user 0.00 s, sys: 0.00 s, total: 0.00 s
1518 846 Wall time: 0.00 s
1519 847 Compiler : 0.78 s
1520 848 """
1521 849
1522 850 # fail immediately if the given expression can't be compiled
1523 851
1524 852 expr = self.shell.prefilter(parameter_s,False)
1525 853
1526 854 # Minimum time above which compilation time will be reported
1527 855 tc_min = 0.1
1528 856
1529 857 try:
1530 858 mode = 'eval'
1531 859 t0 = clock()
1532 860 code = compile(expr,'<timed eval>',mode)
1533 861 tc = clock()-t0
1534 862 except SyntaxError:
1535 863 mode = 'exec'
1536 864 t0 = clock()
1537 865 code = compile(expr,'<timed exec>',mode)
1538 866 tc = clock()-t0
1539 867 # skew measurement as little as possible
1540 868 glob = self.shell.user_ns
1541 869 wtime = time.time
1542 870 # time execution
1543 871 wall_st = wtime()
1544 872 if mode=='eval':
1545 873 st = clock2()
1546 874 out = eval(code, glob, user_locals)
1547 875 end = clock2()
1548 876 else:
1549 877 st = clock2()
1550 878 exec code in glob, user_locals
1551 879 end = clock2()
1552 880 out = None
1553 881 wall_end = wtime()
1554 882 # Compute actual times and report
1555 883 wall_time = wall_end-wall_st
1556 884 cpu_user = end[0]-st[0]
1557 885 cpu_sys = end[1]-st[1]
1558 886 cpu_tot = cpu_user+cpu_sys
1559 887 print "CPU times: user %.2f s, sys: %.2f s, total: %.2f s" % \
1560 888 (cpu_user,cpu_sys,cpu_tot)
1561 889 print "Wall time: %.2f s" % wall_time
1562 890 if tc > tc_min:
1563 891 print "Compiler : %.2f s" % tc
1564 892 return out
1565 893
1566 894 @skip_doctest
1567 895 @line_magic
1568 896 def macro(self, parameter_s=''):
1569 897 """Define a macro for future re-execution. It accepts ranges of history,
1570 898 filenames or string objects.
1571 899
1572 900 Usage:\\
1573 901 %macro [options] name n1-n2 n3-n4 ... n5 .. n6 ...
1574 902
1575 903 Options:
1576 904
1577 905 -r: use 'raw' input. By default, the 'processed' history is used,
1578 906 so that magics are loaded in their transformed version to valid
1579 907 Python. If this option is given, the raw input as typed as the
1580 908 command line is used instead.
1581 909
1582 910 This will define a global variable called `name` which is a string
1583 911 made of joining the slices and lines you specify (n1,n2,... numbers
1584 912 above) from your input history into a single string. This variable
1585 913 acts like an automatic function which re-executes those lines as if
1586 914 you had typed them. You just type 'name' at the prompt and the code
1587 915 executes.
1588 916
1589 917 The syntax for indicating input ranges is described in %history.
1590 918
1591 919 Note: as a 'hidden' feature, you can also use traditional python slice
1592 920 notation, where N:M means numbers N through M-1.
1593 921
1594 922 For example, if your history contains (%hist prints it)::
1595 923
1596 924 44: x=1
1597 925 45: y=3
1598 926 46: z=x+y
1599 927 47: print x
1600 928 48: a=5
1601 929 49: print 'x',x,'y',y
1602 930
1603 931 you can create a macro with lines 44 through 47 (included) and line 49
1604 932 called my_macro with::
1605 933
1606 934 In [55]: %macro my_macro 44-47 49
1607 935
1608 936 Now, typing `my_macro` (without quotes) will re-execute all this code
1609 937 in one pass.
1610 938
1611 939 You don't need to give the line-numbers in order, and any given line
1612 940 number can appear multiple times. You can assemble macros with any
1613 941 lines from your input history in any order.
1614 942
1615 943 The macro is a simple object which holds its value in an attribute,
1616 944 but IPython's display system checks for macros and executes them as
1617 945 code instead of printing them when you type their name.
1618 946
1619 947 You can view a macro's contents by explicitly printing it with::
1620 948
1621 949 print macro_name
1622 950
1623 951 """
1624 952 opts,args = self.parse_options(parameter_s,'r',mode='list')
1625 953 if not args: # List existing macros
1626 954 return sorted(k for k,v in self.shell.user_ns.iteritems() if\
1627 955 isinstance(v, Macro))
1628 956 if len(args) == 1:
1629 957 raise UsageError(
1630 958 "%macro insufficient args; usage '%macro name n1-n2 n3-4...")
1631 959 name, codefrom = args[0], " ".join(args[1:])
1632 960
1633 961 #print 'rng',ranges # dbg
1634 962 try:
1635 963 lines = self.shell.find_user_code(codefrom, 'r' in opts)
1636 964 except (ValueError, TypeError) as e:
1637 965 print e.args[0]
1638 966 return
1639 967 macro = Macro(lines)
1640 968 self.shell.define_macro(name, macro)
1641 969 print 'Macro `%s` created. To execute, type its name (without quotes).' % name
1642 970 print '=== Macro contents: ==='
1643 971 print macro,
1644 972
1645 973
1646 974 @register_magics
1647 975 class AutoMagics(Magics):
1648 976 """Magics that control various autoX behaviors."""
1649 977
1650 978 def __init__(self, shell):
1651 979 super(AutoMagics, self).__init__(shell)
1652 980 # namespace for holding state we may need
1653 981 self._magic_state = Bunch()
1654 982
1655 983 @line_magic
1656 984 def automagic(self, parameter_s=''):
1657 985 """Make magic functions callable without having to type the initial %.
1658 986
1659 987 Without argumentsl toggles on/off (when off, you must call it as
1660 988 %automagic, of course). With arguments it sets the value, and you can
1661 989 use any of (case insensitive):
1662 990
1663 991 - on, 1, True: to activate
1664 992
1665 993 - off, 0, False: to deactivate.
1666 994
1667 995 Note that magic functions have lowest priority, so if there's a
1668 996 variable whose name collides with that of a magic fn, automagic won't
1669 997 work for that function (you get the variable instead). However, if you
1670 998 delete the variable (del var), the previously shadowed magic function
1671 999 becomes visible to automagic again."""
1672 1000
1673 1001 arg = parameter_s.lower()
1674 1002 mman = self.shell.magics_manager
1675 1003 if arg in ('on', '1', 'true'):
1676 1004 val = True
1677 1005 elif arg in ('off', '0', 'false'):
1678 1006 val = False
1679 1007 else:
1680 1008 val = not mman.auto_magic
1681 1009 mman.auto_magic = val
1682 1010 print '\n' + self.shell.magics_manager.auto_status()
1683 1011
1684 1012 @skip_doctest
1685 1013 @line_magic
1686 1014 def autocall(self, parameter_s=''):
1687 1015 """Make functions callable without having to type parentheses.
1688 1016
1689 1017 Usage:
1690 1018
1691 1019 %autocall [mode]
1692 1020
1693 1021 The mode can be one of: 0->Off, 1->Smart, 2->Full. If not given, the
1694 1022 value is toggled on and off (remembering the previous state).
1695 1023
1696 1024 In more detail, these values mean:
1697 1025
1698 1026 0 -> fully disabled
1699 1027
1700 1028 1 -> active, but do not apply if there are no arguments on the line.
1701 1029
1702 1030 In this mode, you get::
1703 1031
1704 1032 In [1]: callable
1705 1033 Out[1]: <built-in function callable>
1706 1034
1707 1035 In [2]: callable 'hello'
1708 1036 ------> callable('hello')
1709 1037 Out[2]: False
1710 1038
1711 1039 2 -> Active always. Even if no arguments are present, the callable
1712 1040 object is called::
1713 1041
1714 1042 In [2]: float
1715 1043 ------> float()
1716 1044 Out[2]: 0.0
1717 1045
1718 1046 Note that even with autocall off, you can still use '/' at the start of
1719 1047 a line to treat the first argument on the command line as a function
1720 1048 and add parentheses to it::
1721 1049
1722 1050 In [8]: /str 43
1723 1051 ------> str(43)
1724 1052 Out[8]: '43'
1725 1053
1726 1054 # all-random (note for auto-testing)
1727 1055 """
1728 1056
1729 1057 if parameter_s:
1730 1058 arg = int(parameter_s)
1731 1059 else:
1732 1060 arg = 'toggle'
1733 1061
1734 1062 if not arg in (0, 1, 2,'toggle'):
1735 1063 error('Valid modes: (0->Off, 1->Smart, 2->Full')
1736 1064 return
1737 1065
1738 1066 if arg in (0, 1, 2):
1739 1067 self.shell.autocall = arg
1740 1068 else: # toggle
1741 1069 if self.shell.autocall:
1742 1070 self._magic_state.autocall_save = self.shell.autocall
1743 1071 self.shell.autocall = 0
1744 1072 else:
1745 1073 try:
1746 1074 self.shell.autocall = self._magic_state.autocall_save
1747 1075 except AttributeError:
1748 1076 self.shell.autocall = self._magic_state.autocall_save = 1
1749 1077
1750 1078 print "Automatic calling is:",['OFF','Smart','Full'][self.shell.autocall]
1751 1079
1752 1080
1753 1081 @register_magics
1754 1082 class OSMagics(Magics):
1755 1083 """Magics to interact with the underlying OS (shell-type functionality).
1756 1084 """
1757 1085
1758 1086 @skip_doctest
1759 1087 @line_magic
1760 1088 def alias(self, parameter_s=''):
1761 1089 """Define an alias for a system command.
1762 1090
1763 1091 '%alias alias_name cmd' defines 'alias_name' as an alias for 'cmd'
1764 1092
1765 1093 Then, typing 'alias_name params' will execute the system command 'cmd
1766 1094 params' (from your underlying operating system).
1767 1095
1768 1096 Aliases have lower precedence than magic functions and Python normal
1769 1097 variables, so if 'foo' is both a Python variable and an alias, the
1770 1098 alias can not be executed until 'del foo' removes the Python variable.
1771 1099
1772 1100 You can use the %l specifier in an alias definition to represent the
1773 1101 whole line when the alias is called. For example::
1774 1102
1775 1103 In [2]: alias bracket echo "Input in brackets: <%l>"
1776 1104 In [3]: bracket hello world
1777 1105 Input in brackets: <hello world>
1778 1106
1779 1107 You can also define aliases with parameters using %s specifiers (one
1780 1108 per parameter)::
1781 1109
1782 1110 In [1]: alias parts echo first %s second %s
1783 1111 In [2]: %parts A B
1784 1112 first A second B
1785 1113 In [3]: %parts A
1786 1114 Incorrect number of arguments: 2 expected.
1787 1115 parts is an alias to: 'echo first %s second %s'
1788 1116
1789 1117 Note that %l and %s are mutually exclusive. You can only use one or
1790 1118 the other in your aliases.
1791 1119
1792 1120 Aliases expand Python variables just like system calls using ! or !!
1793 1121 do: all expressions prefixed with '$' get expanded. For details of
1794 1122 the semantic rules, see PEP-215:
1795 1123 http://www.python.org/peps/pep-0215.html. This is the library used by
1796 1124 IPython for variable expansion. If you want to access a true shell
1797 1125 variable, an extra $ is necessary to prevent its expansion by
1798 1126 IPython::
1799 1127
1800 1128 In [6]: alias show echo
1801 1129 In [7]: PATH='A Python string'
1802 1130 In [8]: show $PATH
1803 1131 A Python string
1804 1132 In [9]: show $$PATH
1805 1133 /usr/local/lf9560/bin:/usr/local/intel/compiler70/ia32/bin:...
1806 1134
1807 1135 You can use the alias facility to acess all of $PATH. See the %rehash
1808 1136 and %rehashx functions, which automatically create aliases for the
1809 1137 contents of your $PATH.
1810 1138
1811 1139 If called with no parameters, %alias prints the current alias table."""
1812 1140
1813 1141 par = parameter_s.strip()
1814 1142 if not par:
1815 1143 aliases = sorted(self.shell.alias_manager.aliases)
1816 1144 # stored = self.shell.db.get('stored_aliases', {} )
1817 1145 # for k, v in stored:
1818 1146 # atab.append(k, v[0])
1819 1147
1820 1148 print "Total number of aliases:", len(aliases)
1821 1149 sys.stdout.flush()
1822 1150 return aliases
1823 1151
1824 1152 # Now try to define a new one
1825 1153 try:
1826 1154 alias,cmd = par.split(None, 1)
1827 1155 except:
1828 1156 print oinspect.getdoc(self.alias)
1829 1157 else:
1830 1158 self.shell.alias_manager.soft_define_alias(alias, cmd)
1831 1159 # end magic_alias
1832 1160
1833 1161 @line_magic
1834 1162 def unalias(self, parameter_s=''):
1835 1163 """Remove an alias"""
1836 1164
1837 1165 aname = parameter_s.strip()
1838 1166 self.shell.alias_manager.undefine_alias(aname)
1839 1167 stored = self.shell.db.get('stored_aliases', {} )
1840 1168 if aname in stored:
1841 1169 print "Removing %stored alias",aname
1842 1170 del stored[aname]
1843 1171 self.shell.db['stored_aliases'] = stored
1844 1172
1845 1173 @line_magic
1846 1174 def rehashx(self, parameter_s=''):
1847 1175 """Update the alias table with all executable files in $PATH.
1848 1176
1849 1177 This version explicitly checks that every entry in $PATH is a file
1850 1178 with execute access (os.X_OK), so it is much slower than %rehash.
1851 1179
1852 1180 Under Windows, it checks executability as a match against a
1853 1181 '|'-separated string of extensions, stored in the IPython config
1854 1182 variable win_exec_ext. This defaults to 'exe|com|bat'.
1855 1183
1856 1184 This function also resets the root module cache of module completer,
1857 1185 used on slow filesystems.
1858 1186 """
1859 1187 from IPython.core.alias import InvalidAliasError
1860 1188
1861 1189 # for the benefit of module completer in ipy_completers.py
1862 1190 del self.shell.db['rootmodules']
1863 1191
1864 1192 path = [os.path.abspath(os.path.expanduser(p)) for p in
1865 1193 os.environ.get('PATH','').split(os.pathsep)]
1866 1194 path = filter(os.path.isdir,path)
1867 1195
1868 1196 syscmdlist = []
1869 1197 # Now define isexec in a cross platform manner.
1870 1198 if os.name == 'posix':
1871 1199 isexec = lambda fname:os.path.isfile(fname) and \
1872 1200 os.access(fname,os.X_OK)
1873 1201 else:
1874 1202 try:
1875 1203 winext = os.environ['pathext'].replace(';','|').replace('.','')
1876 1204 except KeyError:
1877 1205 winext = 'exe|com|bat|py'
1878 1206 if 'py' not in winext:
1879 1207 winext += '|py'
1880 1208 execre = re.compile(r'(.*)\.(%s)$' % winext,re.IGNORECASE)
1881 1209 isexec = lambda fname:os.path.isfile(fname) and execre.match(fname)
1882 1210 savedir = os.getcwdu()
1883 1211
1884 1212 # Now walk the paths looking for executables to alias.
1885 1213 try:
1886 1214 # write the whole loop for posix/Windows so we don't have an if in
1887 1215 # the innermost part
1888 1216 if os.name == 'posix':
1889 1217 for pdir in path:
1890 1218 os.chdir(pdir)
1891 1219 for ff in os.listdir(pdir):
1892 1220 if isexec(ff):
1893 1221 try:
1894 1222 # Removes dots from the name since ipython
1895 1223 # will assume names with dots to be python.
1896 1224 self.shell.alias_manager.define_alias(
1897 1225 ff.replace('.',''), ff)
1898 1226 except InvalidAliasError:
1899 1227 pass
1900 1228 else:
1901 1229 syscmdlist.append(ff)
1902 1230 else:
1903 1231 no_alias = self.shell.alias_manager.no_alias
1904 1232 for pdir in path:
1905 1233 os.chdir(pdir)
1906 1234 for ff in os.listdir(pdir):
1907 1235 base, ext = os.path.splitext(ff)
1908 1236 if isexec(ff) and base.lower() not in no_alias:
1909 1237 if ext.lower() == '.exe':
1910 1238 ff = base
1911 1239 try:
1912 1240 # Removes dots from the name since ipython
1913 1241 # will assume names with dots to be python.
1914 1242 self.shell.alias_manager.define_alias(
1915 1243 base.lower().replace('.',''), ff)
1916 1244 except InvalidAliasError:
1917 1245 pass
1918 1246 syscmdlist.append(ff)
1919 1247 self.shell.db['syscmdlist'] = syscmdlist
1920 1248 finally:
1921 1249 os.chdir(savedir)
1922 1250
1923 1251 @skip_doctest
1924 1252 @line_magic
1925 1253 def pwd(self, parameter_s=''):
1926 1254 """Return the current working directory path.
1927 1255
1928 1256 Examples
1929 1257 --------
1930 1258 ::
1931 1259
1932 1260 In [9]: pwd
1933 1261 Out[9]: '/home/tsuser/sprint/ipython'
1934 1262 """
1935 1263 return os.getcwdu()
1936 1264
1937 1265 @skip_doctest
1938 1266 @line_magic
1939 1267 def cd(self, parameter_s=''):
1940 1268 """Change the current working directory.
1941 1269
1942 1270 This command automatically maintains an internal list of directories
1943 1271 you visit during your IPython session, in the variable _dh. The
1944 1272 command %dhist shows this history nicely formatted. You can also
1945 1273 do 'cd -<tab>' to see directory history conveniently.
1946 1274
1947 1275 Usage:
1948 1276
1949 1277 cd 'dir': changes to directory 'dir'.
1950 1278
1951 1279 cd -: changes to the last visited directory.
1952 1280
1953 1281 cd -<n>: changes to the n-th directory in the directory history.
1954 1282
1955 1283 cd --foo: change to directory that matches 'foo' in history
1956 1284
1957 1285 cd -b <bookmark_name>: jump to a bookmark set by %bookmark
1958 1286 (note: cd <bookmark_name> is enough if there is no
1959 1287 directory <bookmark_name>, but a bookmark with the name exists.)
1960 1288 'cd -b <tab>' allows you to tab-complete bookmark names.
1961 1289
1962 1290 Options:
1963 1291
1964 1292 -q: quiet. Do not print the working directory after the cd command is
1965 1293 executed. By default IPython's cd command does print this directory,
1966 1294 since the default prompts do not display path information.
1967 1295
1968 1296 Note that !cd doesn't work for this purpose because the shell where
1969 1297 !command runs is immediately discarded after executing 'command'.
1970 1298
1971 1299 Examples
1972 1300 --------
1973 1301 ::
1974 1302
1975 1303 In [10]: cd parent/child
1976 1304 /home/tsuser/parent/child
1977 1305 """
1978 1306
1979 1307 #bkms = self.shell.persist.get("bookmarks",{})
1980 1308
1981 1309 oldcwd = os.getcwdu()
1982 1310 numcd = re.match(r'(-)(\d+)$',parameter_s)
1983 1311 # jump in directory history by number
1984 1312 if numcd:
1985 1313 nn = int(numcd.group(2))
1986 1314 try:
1987 1315 ps = self.shell.user_ns['_dh'][nn]
1988 1316 except IndexError:
1989 1317 print 'The requested directory does not exist in history.'
1990 1318 return
1991 1319 else:
1992 1320 opts = {}
1993 1321 elif parameter_s.startswith('--'):
1994 1322 ps = None
1995 1323 fallback = None
1996 1324 pat = parameter_s[2:]
1997 1325 dh = self.shell.user_ns['_dh']
1998 1326 # first search only by basename (last component)
1999 1327 for ent in reversed(dh):
2000 1328 if pat in os.path.basename(ent) and os.path.isdir(ent):
2001 1329 ps = ent
2002 1330 break
2003 1331
2004 1332 if fallback is None and pat in ent and os.path.isdir(ent):
2005 1333 fallback = ent
2006 1334
2007 1335 # if we have no last part match, pick the first full path match
2008 1336 if ps is None:
2009 1337 ps = fallback
2010 1338
2011 1339 if ps is None:
2012 1340 print "No matching entry in directory history"
2013 1341 return
2014 1342 else:
2015 1343 opts = {}
2016 1344
2017 1345
2018 1346 else:
2019 1347 #turn all non-space-escaping backslashes to slashes,
2020 1348 # for c:\windows\directory\names\
2021 1349 parameter_s = re.sub(r'\\(?! )','/', parameter_s)
2022 1350 opts,ps = self.parse_options(parameter_s,'qb',mode='string')
2023 1351 # jump to previous
2024 1352 if ps == '-':
2025 1353 try:
2026 1354 ps = self.shell.user_ns['_dh'][-2]
2027 1355 except IndexError:
2028 1356 raise UsageError('%cd -: No previous directory to change to.')
2029 1357 # jump to bookmark if needed
2030 1358 else:
2031 1359 if not os.path.isdir(ps) or opts.has_key('b'):
2032 1360 bkms = self.shell.db.get('bookmarks', {})
2033 1361
2034 1362 if bkms.has_key(ps):
2035 1363 target = bkms[ps]
2036 1364 print '(bookmark:%s) -> %s' % (ps,target)
2037 1365 ps = target
2038 1366 else:
2039 1367 if opts.has_key('b'):
2040 1368 raise UsageError("Bookmark '%s' not found. "
2041 1369 "Use '%%bookmark -l' to see your bookmarks." % ps)
2042 1370
2043 1371 # strip extra quotes on Windows, because os.chdir doesn't like them
2044 1372 ps = unquote_filename(ps)
2045 1373 # at this point ps should point to the target dir
2046 1374 if ps:
2047 1375 try:
2048 1376 os.chdir(os.path.expanduser(ps))
2049 1377 if hasattr(self.shell, 'term_title') and self.shell.term_title:
2050 1378 set_term_title('IPython: ' + abbrev_cwd())
2051 1379 except OSError:
2052 1380 print sys.exc_info()[1]
2053 1381 else:
2054 1382 cwd = os.getcwdu()
2055 1383 dhist = self.shell.user_ns['_dh']
2056 1384 if oldcwd != cwd:
2057 1385 dhist.append(cwd)
2058 1386 self.shell.db['dhist'] = compress_dhist(dhist)[-100:]
2059 1387
2060 1388 else:
2061 1389 os.chdir(self.shell.home_dir)
2062 1390 if hasattr(self.shell, 'term_title') and self.shell.term_title:
2063 1391 set_term_title('IPython: ' + '~')
2064 1392 cwd = os.getcwdu()
2065 1393 dhist = self.shell.user_ns['_dh']
2066 1394
2067 1395 if oldcwd != cwd:
2068 1396 dhist.append(cwd)
2069 1397 self.shell.db['dhist'] = compress_dhist(dhist)[-100:]
2070 1398 if not 'q' in opts and self.shell.user_ns['_dh']:
2071 1399 print self.shell.user_ns['_dh'][-1]
2072 1400
2073 1401
2074 1402 @line_magic
2075 1403 def env(self, parameter_s=''):
2076 1404 """List environment variables."""
2077 1405
2078 1406 return dict(os.environ)
2079 1407
2080 1408 @line_magic
2081 1409 def pushd(self, parameter_s=''):
2082 1410 """Place the current dir on stack and change directory.
2083 1411
2084 1412 Usage:\\
2085 1413 %pushd ['dirname']
2086 1414 """
2087 1415
2088 1416 dir_s = self.shell.dir_stack
2089 1417 tgt = os.path.expanduser(unquote_filename(parameter_s))
2090 1418 cwd = os.getcwdu().replace(self.shell.home_dir,'~')
2091 1419 if tgt:
2092 1420 self.cd(parameter_s)
2093 1421 dir_s.insert(0,cwd)
2094 1422 return self.shell.magic('dirs')
2095 1423
2096 1424 @line_magic
2097 1425 def popd(self, parameter_s=''):
2098 1426 """Change to directory popped off the top of the stack.
2099 1427 """
2100 1428 if not self.shell.dir_stack:
2101 1429 raise UsageError("%popd on empty stack")
2102 1430 top = self.shell.dir_stack.pop(0)
2103 1431 self.cd(top)
2104 1432 print "popd ->",top
2105 1433
2106 1434 @line_magic
2107 1435 def dirs(self, parameter_s=''):
2108 1436 """Return the current directory stack."""
2109 1437
2110 1438 return self.shell.dir_stack
2111 1439
2112 1440 @line_magic
2113 1441 def dhist(self, parameter_s=''):
2114 1442 """Print your history of visited directories.
2115 1443
2116 1444 %dhist -> print full history\\
2117 1445 %dhist n -> print last n entries only\\
2118 1446 %dhist n1 n2 -> print entries between n1 and n2 (n1 not included)\\
2119 1447
2120 1448 This history is automatically maintained by the %cd command, and
2121 1449 always available as the global list variable _dh. You can use %cd -<n>
2122 1450 to go to directory number <n>.
2123 1451
2124 1452 Note that most of time, you should view directory history by entering
2125 1453 cd -<TAB>.
2126 1454
2127 1455 """
2128 1456
2129 1457 dh = self.shell.user_ns['_dh']
2130 1458 if parameter_s:
2131 1459 try:
2132 1460 args = map(int,parameter_s.split())
2133 1461 except:
2134 1462 self.arg_err(self.dhist)
2135 1463 return
2136 1464 if len(args) == 1:
2137 1465 ini,fin = max(len(dh)-(args[0]),0),len(dh)
2138 1466 elif len(args) == 2:
2139 1467 ini,fin = args
2140 1468 else:
2141 1469 self.arg_err(self.dhist)
2142 1470 return
2143 1471 else:
2144 1472 ini,fin = 0,len(dh)
2145 1473 nlprint(dh,
2146 1474 header = 'Directory history (kept in _dh)',
2147 1475 start=ini,stop=fin)
2148 1476
2149 1477 @skip_doctest
2150 1478 @line_magic
2151 1479 def sc(self, parameter_s=''):
2152 1480 """Shell capture - execute a shell command and capture its output.
2153 1481
2154 1482 DEPRECATED. Suboptimal, retained for backwards compatibility.
2155 1483
2156 1484 You should use the form 'var = !command' instead. Example:
2157 1485
2158 1486 "%sc -l myfiles = ls ~" should now be written as
2159 1487
2160 1488 "myfiles = !ls ~"
2161 1489
2162 1490 myfiles.s, myfiles.l and myfiles.n still apply as documented
2163 1491 below.
2164 1492
2165 1493 --
2166 1494 %sc [options] varname=command
2167 1495
2168 1496 IPython will run the given command using commands.getoutput(), and
2169 1497 will then update the user's interactive namespace with a variable
2170 1498 called varname, containing the value of the call. Your command can
2171 1499 contain shell wildcards, pipes, etc.
2172 1500
2173 1501 The '=' sign in the syntax is mandatory, and the variable name you
2174 1502 supply must follow Python's standard conventions for valid names.
2175 1503
2176 1504 (A special format without variable name exists for internal use)
2177 1505
2178 1506 Options:
2179 1507
2180 1508 -l: list output. Split the output on newlines into a list before
2181 1509 assigning it to the given variable. By default the output is stored
2182 1510 as a single string.
2183 1511
2184 1512 -v: verbose. Print the contents of the variable.
2185 1513
2186 1514 In most cases you should not need to split as a list, because the
2187 1515 returned value is a special type of string which can automatically
2188 1516 provide its contents either as a list (split on newlines) or as a
2189 1517 space-separated string. These are convenient, respectively, either
2190 1518 for sequential processing or to be passed to a shell command.
2191 1519
2192 1520 For example::
2193 1521
2194 1522 # Capture into variable a
2195 1523 In [1]: sc a=ls *py
2196 1524
2197 1525 # a is a string with embedded newlines
2198 1526 In [2]: a
2199 1527 Out[2]: 'setup.py\\nwin32_manual_post_install.py'
2200 1528
2201 1529 # which can be seen as a list:
2202 1530 In [3]: a.l
2203 1531 Out[3]: ['setup.py', 'win32_manual_post_install.py']
2204 1532
2205 1533 # or as a whitespace-separated string:
2206 1534 In [4]: a.s
2207 1535 Out[4]: 'setup.py win32_manual_post_install.py'
2208 1536
2209 1537 # a.s is useful to pass as a single command line:
2210 1538 In [5]: !wc -l $a.s
2211 1539 146 setup.py
2212 1540 130 win32_manual_post_install.py
2213 1541 276 total
2214 1542
2215 1543 # while the list form is useful to loop over:
2216 1544 In [6]: for f in a.l:
2217 1545 ...: !wc -l $f
2218 1546 ...:
2219 1547 146 setup.py
2220 1548 130 win32_manual_post_install.py
2221 1549
2222 1550 Similarly, the lists returned by the -l option are also special, in
2223 1551 the sense that you can equally invoke the .s attribute on them to
2224 1552 automatically get a whitespace-separated string from their contents::
2225 1553
2226 1554 In [7]: sc -l b=ls *py
2227 1555
2228 1556 In [8]: b
2229 1557 Out[8]: ['setup.py', 'win32_manual_post_install.py']
2230 1558
2231 1559 In [9]: b.s
2232 1560 Out[9]: 'setup.py win32_manual_post_install.py'
2233 1561
2234 1562 In summary, both the lists and strings used for output capture have
2235 1563 the following special attributes::
2236 1564
2237 1565 .l (or .list) : value as list.
2238 1566 .n (or .nlstr): value as newline-separated string.
2239 1567 .s (or .spstr): value as space-separated string.
2240 1568 """
2241 1569
2242 1570 opts,args = self.parse_options(parameter_s,'lv')
2243 1571 # Try to get a variable name and command to run
2244 1572 try:
2245 1573 # the variable name must be obtained from the parse_options
2246 1574 # output, which uses shlex.split to strip options out.
2247 1575 var,_ = args.split('=',1)
2248 1576 var = var.strip()
2249 1577 # But the command has to be extracted from the original input
2250 1578 # parameter_s, not on what parse_options returns, to avoid the
2251 1579 # quote stripping which shlex.split performs on it.
2252 1580 _,cmd = parameter_s.split('=',1)
2253 1581 except ValueError:
2254 1582 var,cmd = '',''
2255 1583 # If all looks ok, proceed
2256 1584 split = 'l' in opts
2257 1585 out = self.shell.getoutput(cmd, split=split)
2258 1586 if opts.has_key('v'):
2259 1587 print '%s ==\n%s' % (var,pformat(out))
2260 1588 if var:
2261 1589 self.shell.user_ns.update({var:out})
2262 1590 else:
2263 1591 return out
2264 1592
2265 1593 @line_magic
2266 1594 def sx(self, parameter_s=''):
2267 1595 """Shell execute - run a shell command and capture its output.
2268 1596
2269 1597 %sx command
2270 1598
2271 1599 IPython will run the given command using commands.getoutput(), and
2272 1600 return the result formatted as a list (split on '\\n'). Since the
2273 1601 output is _returned_, it will be stored in ipython's regular output
2274 1602 cache Out[N] and in the '_N' automatic variables.
2275 1603
2276 1604 Notes:
2277 1605
2278 1606 1) If an input line begins with '!!', then %sx is automatically
2279 1607 invoked. That is, while::
2280 1608
2281 1609 !ls
2282 1610
2283 1611 causes ipython to simply issue system('ls'), typing::
2284 1612
2285 1613 !!ls
2286 1614
2287 1615 is a shorthand equivalent to::
2288 1616
2289 1617 %sx ls
2290 1618
2291 1619 2) %sx differs from %sc in that %sx automatically splits into a list,
2292 1620 like '%sc -l'. The reason for this is to make it as easy as possible
2293 1621 to process line-oriented shell output via further python commands.
2294 1622 %sc is meant to provide much finer control, but requires more
2295 1623 typing.
2296 1624
2297 1625 3) Just like %sc -l, this is a list with special attributes:
2298 1626 ::
2299 1627
2300 1628 .l (or .list) : value as list.
2301 1629 .n (or .nlstr): value as newline-separated string.
2302 1630 .s (or .spstr): value as whitespace-separated string.
2303 1631
2304 1632 This is very useful when trying to use such lists as arguments to
2305 1633 system commands."""
2306 1634
2307 1635 if parameter_s:
2308 1636 return self.shell.getoutput(parameter_s)
2309 1637
2310 1638
2311 1639 @line_magic
2312 1640 def bookmark(self, parameter_s=''):
2313 1641 """Manage IPython's bookmark system.
2314 1642
2315 1643 %bookmark <name> - set bookmark to current dir
2316 1644 %bookmark <name> <dir> - set bookmark to <dir>
2317 1645 %bookmark -l - list all bookmarks
2318 1646 %bookmark -d <name> - remove bookmark
2319 1647 %bookmark -r - remove all bookmarks
2320 1648
2321 1649 You can later on access a bookmarked folder with::
2322 1650
2323 1651 %cd -b <name>
2324 1652
2325 1653 or simply '%cd <name>' if there is no directory called <name> AND
2326 1654 there is such a bookmark defined.
2327 1655
2328 1656 Your bookmarks persist through IPython sessions, but they are
2329 1657 associated with each profile."""
2330 1658
2331 1659 opts,args = self.parse_options(parameter_s,'drl',mode='list')
2332 1660 if len(args) > 2:
2333 1661 raise UsageError("%bookmark: too many arguments")
2334 1662
2335 1663 bkms = self.shell.db.get('bookmarks',{})
2336 1664
2337 1665 if opts.has_key('d'):
2338 1666 try:
2339 1667 todel = args[0]
2340 1668 except IndexError:
2341 1669 raise UsageError(
2342 1670 "%bookmark -d: must provide a bookmark to delete")
2343 1671 else:
2344 1672 try:
2345 1673 del bkms[todel]
2346 1674 except KeyError:
2347 1675 raise UsageError(
2348 1676 "%%bookmark -d: Can't delete bookmark '%s'" % todel)
2349 1677
2350 1678 elif opts.has_key('r'):
2351 1679 bkms = {}
2352 1680 elif opts.has_key('l'):
2353 1681 bks = bkms.keys()
2354 1682 bks.sort()
2355 1683 if bks:
2356 1684 size = max(map(len,bks))
2357 1685 else:
2358 1686 size = 0
2359 1687 fmt = '%-'+str(size)+'s -> %s'
2360 1688 print 'Current bookmarks:'
2361 1689 for bk in bks:
2362 1690 print fmt % (bk,bkms[bk])
2363 1691 else:
2364 1692 if not args:
2365 1693 raise UsageError("%bookmark: You must specify the bookmark name")
2366 1694 elif len(args)==1:
2367 1695 bkms[args[0]] = os.getcwdu()
2368 1696 elif len(args)==2:
2369 1697 bkms[args[0]] = args[1]
2370 1698 self.shell.db['bookmarks'] = bkms
2371 1699
2372 1700 @line_magic
2373 1701 def pycat(self, parameter_s=''):
2374 1702 """Show a syntax-highlighted file through a pager.
2375 1703
2376 1704 This magic is similar to the cat utility, but it will assume the file
2377 1705 to be Python source and will show it with syntax highlighting. """
2378 1706
2379 1707 try:
2380 1708 filename = get_py_filename(parameter_s)
2381 1709 cont = file_read(filename)
2382 1710 except IOError:
2383 1711 try:
2384 1712 cont = eval(parameter_s, self.shell.user_ns)
2385 1713 except NameError:
2386 1714 cont = None
2387 1715 if cont is None:
2388 1716 print "Error: no such file or variable"
2389 1717 return
2390 1718
2391 1719 page.page(self.shell.pycolorize(cont))
2392 1720
2393 1721
2394 1722 @register_magics
2395 1723 class LoggingMagics(Magics):
2396 1724 """Magics related to all logging machinery."""
2397 1725
2398 1726 @line_magic
2399 1727 def logstart(self, parameter_s=''):
2400 1728 """Start logging anywhere in a session.
2401 1729
2402 1730 %logstart [-o|-r|-t] [log_name [log_mode]]
2403 1731
2404 1732 If no name is given, it defaults to a file named 'ipython_log.py' in your
2405 1733 current directory, in 'rotate' mode (see below).
2406 1734
2407 1735 '%logstart name' saves to file 'name' in 'backup' mode. It saves your
2408 1736 history up to that point and then continues logging.
2409 1737
2410 1738 %logstart takes a second optional parameter: logging mode. This can be one
2411 1739 of (note that the modes are given unquoted):\\
2412 1740 append: well, that says it.\\
2413 1741 backup: rename (if exists) to name~ and start name.\\
2414 1742 global: single logfile in your home dir, appended to.\\
2415 1743 over : overwrite existing log.\\
2416 1744 rotate: create rotating logs name.1~, name.2~, etc.
2417 1745
2418 1746 Options:
2419 1747
2420 1748 -o: log also IPython's output. In this mode, all commands which
2421 1749 generate an Out[NN] prompt are recorded to the logfile, right after
2422 1750 their corresponding input line. The output lines are always
2423 1751 prepended with a '#[Out]# ' marker, so that the log remains valid
2424 1752 Python code.
2425 1753
2426 1754 Since this marker is always the same, filtering only the output from
2427 1755 a log is very easy, using for example a simple awk call::
2428 1756
2429 1757 awk -F'#\\[Out\\]# ' '{if($2) {print $2}}' ipython_log.py
2430 1758
2431 1759 -r: log 'raw' input. Normally, IPython's logs contain the processed
2432 1760 input, so that user lines are logged in their final form, converted
2433 1761 into valid Python. For example, %Exit is logged as
2434 1762 _ip.magic("Exit"). If the -r flag is given, all input is logged
2435 1763 exactly as typed, with no transformations applied.
2436 1764
2437 1765 -t: put timestamps before each input line logged (these are put in
2438 1766 comments)."""
2439 1767
2440 1768 opts,par = self.parse_options(parameter_s,'ort')
2441 1769 log_output = 'o' in opts
2442 1770 log_raw_input = 'r' in opts
2443 1771 timestamp = 't' in opts
2444 1772
2445 1773 logger = self.shell.logger
2446 1774
2447 1775 # if no args are given, the defaults set in the logger constructor by
2448 1776 # ipython remain valid
2449 1777 if par:
2450 1778 try:
2451 1779 logfname,logmode = par.split()
2452 1780 except:
2453 1781 logfname = par
2454 1782 logmode = 'backup'
2455 1783 else:
2456 1784 logfname = logger.logfname
2457 1785 logmode = logger.logmode
2458 1786 # put logfname into rc struct as if it had been called on the command
2459 1787 # line, so it ends up saved in the log header Save it in case we need
2460 1788 # to restore it...
2461 1789 old_logfile = self.shell.logfile
2462 1790 if logfname:
2463 1791 logfname = os.path.expanduser(logfname)
2464 1792 self.shell.logfile = logfname
2465 1793
2466 1794 loghead = '# IPython log file\n\n'
2467 1795 try:
2468 1796 logger.logstart(logfname, loghead, logmode, log_output, timestamp,
2469 1797 log_raw_input)
2470 1798 except:
2471 1799 self.shell.logfile = old_logfile
2472 1800 warn("Couldn't start log: %s" % sys.exc_info()[1])
2473 1801 else:
2474 1802 # log input history up to this point, optionally interleaving
2475 1803 # output if requested
2476 1804
2477 1805 if timestamp:
2478 1806 # disable timestamping for the previous history, since we've
2479 1807 # lost those already (no time machine here).
2480 1808 logger.timestamp = False
2481 1809
2482 1810 if log_raw_input:
2483 1811 input_hist = self.shell.history_manager.input_hist_raw
2484 1812 else:
2485 1813 input_hist = self.shell.history_manager.input_hist_parsed
2486 1814
2487 1815 if log_output:
2488 1816 log_write = logger.log_write
2489 1817 output_hist = self.shell.history_manager.output_hist
2490 1818 for n in range(1,len(input_hist)-1):
2491 1819 log_write(input_hist[n].rstrip() + '\n')
2492 1820 if n in output_hist:
2493 1821 log_write(repr(output_hist[n]),'output')
2494 1822 else:
2495 1823 logger.log_write('\n'.join(input_hist[1:]))
2496 1824 logger.log_write('\n')
2497 1825 if timestamp:
2498 1826 # re-enable timestamping
2499 1827 logger.timestamp = True
2500 1828
2501 1829 print ('Activating auto-logging. '
2502 1830 'Current session state plus future input saved.')
2503 1831 logger.logstate()
2504 1832
2505 1833 @line_magic
2506 1834 def logstop(self, parameter_s=''):
2507 1835 """Fully stop logging and close log file.
2508 1836
2509 1837 In order to start logging again, a new %logstart call needs to be made,
2510 1838 possibly (though not necessarily) with a new filename, mode and other
2511 1839 options."""
2512 1840 self.logger.logstop()
2513 1841
2514 1842 @line_magic
2515 1843 def logoff(self, parameter_s=''):
2516 1844 """Temporarily stop logging.
2517 1845
2518 1846 You must have previously started logging."""
2519 1847 self.shell.logger.switch_log(0)
2520 1848
2521 1849 @line_magic
2522 1850 def logon(self, parameter_s=''):
2523 1851 """Restart logging.
2524 1852
2525 1853 This function is for restarting logging which you've temporarily
2526 1854 stopped with %logoff. For starting logging for the first time, you
2527 1855 must use the %logstart function, which allows you to specify an
2528 1856 optional log filename."""
2529 1857
2530 1858 self.shell.logger.switch_log(1)
2531 1859
2532 1860 @line_magic
2533 1861 def logstate(self, parameter_s=''):
2534 1862 """Print the status of the logging system."""
2535 1863
2536 1864 self.shell.logger.logstate()
2537 1865
2538 1866
2539 1867 @register_magics
2540 1868 class ExtensionsMagics(Magics):
2541 1869 """Magics to manage the IPython extensions system."""
2542 1870
2543 1871 @line_magic
2544 1872 def install_ext(self, parameter_s=''):
2545 1873 """Download and install an extension from a URL, e.g.::
2546 1874
2547 1875 %install_ext https://bitbucket.org/birkenfeld/ipython-physics/raw/d1310a2ab15d/physics.py
2548 1876
2549 1877 The URL should point to an importable Python module - either a .py file
2550 1878 or a .zip file.
2551 1879
2552 1880 Parameters:
2553 1881
2554 1882 -n filename : Specify a name for the file, rather than taking it from
2555 1883 the URL.
2556 1884 """
2557 1885 opts, args = self.parse_options(parameter_s, 'n:')
2558 1886 try:
2559 1887 filename = self.shell.extension_manager.install_extension(args,
2560 1888 opts.get('n'))
2561 1889 except ValueError as e:
2562 1890 print e
2563 1891 return
2564 1892
2565 1893 filename = os.path.basename(filename)
2566 1894 print "Installed %s. To use it, type:" % filename
2567 1895 print " %%load_ext %s" % os.path.splitext(filename)[0]
2568 1896
2569 1897
2570 1898 @line_magic
2571 1899 def load_ext(self, module_str):
2572 1900 """Load an IPython extension by its module name."""
2573 1901 return self.shell.extension_manager.load_extension(module_str)
2574 1902
2575 1903 @line_magic
2576 1904 def unload_ext(self, module_str):
2577 1905 """Unload an IPython extension by its module name."""
2578 1906 self.shell.extension_manager.unload_extension(module_str)
2579 1907
2580 1908 @line_magic
2581 1909 def reload_ext(self, module_str):
2582 1910 """Reload an IPython extension by its module name."""
2583 1911 self.shell.extension_manager.reload_extension(module_str)
2584 1912
2585 1913
2586 1914 @register_magics
2587 1915 class PylabMagics(Magics):
2588 1916 """Magics related to matplotlib's pylab support"""
2589 1917
2590 1918 @skip_doctest
2591 1919 @line_magic
2592 1920 def pylab(self, parameter_s=''):
2593 1921 """Load numpy and matplotlib to work interactively.
2594 1922
2595 1923 %pylab [GUINAME]
2596 1924
2597 1925 This function lets you activate pylab (matplotlib, numpy and
2598 1926 interactive support) at any point during an IPython session.
2599 1927
2600 1928 It will import at the top level numpy as np, pyplot as plt, matplotlib,
2601 1929 pylab and mlab, as well as all names from numpy and pylab.
2602 1930
2603 1931 If you are using the inline matplotlib backend for embedded figures,
2604 1932 you can adjust its behavior via the %config magic::
2605 1933
2606 1934 # enable SVG figures, necessary for SVG+XHTML export in the qtconsole
2607 1935 In [1]: %config InlineBackend.figure_format = 'svg'
2608 1936
2609 1937 # change the behavior of closing all figures at the end of each
2610 1938 # execution (cell), or allowing reuse of active figures across
2611 1939 # cells:
2612 1940 In [2]: %config InlineBackend.close_figures = False
2613 1941
2614 1942 Parameters
2615 1943 ----------
2616 1944 guiname : optional
2617 1945 One of the valid arguments to the %gui magic ('qt', 'wx', 'gtk',
2618 1946 'osx' or 'tk'). If given, the corresponding Matplotlib backend is
2619 1947 used, otherwise matplotlib's default (which you can override in your
2620 1948 matplotlib config file) is used.
2621 1949
2622 1950 Examples
2623 1951 --------
2624 1952 In this case, where the MPL default is TkAgg::
2625 1953
2626 1954 In [2]: %pylab
2627 1955
2628 1956 Welcome to pylab, a matplotlib-based Python environment.
2629 1957 Backend in use: TkAgg
2630 1958 For more information, type 'help(pylab)'.
2631 1959
2632 1960 But you can explicitly request a different backend::
2633 1961
2634 1962 In [3]: %pylab qt
2635 1963
2636 1964 Welcome to pylab, a matplotlib-based Python environment.
2637 1965 Backend in use: Qt4Agg
2638 1966 For more information, type 'help(pylab)'.
2639 1967 """
2640 1968
2641 1969 if Application.initialized():
2642 1970 app = Application.instance()
2643 1971 try:
2644 1972 import_all_status = app.pylab_import_all
2645 1973 except AttributeError:
2646 1974 import_all_status = True
2647 1975 else:
2648 1976 import_all_status = True
2649 1977
2650 1978 self.shell.enable_pylab(parameter_s, import_all=import_all_status)
2651 1979
2652 1980
2653 1981 @register_magics
2654 1982 class DeprecatedMagics(Magics):
2655 1983 """Magics slated for later removal."""
2656 1984
2657 1985 @line_magic
2658 1986 def install_profiles(self, parameter_s=''):
2659 1987 """%install_profiles has been deprecated."""
2660 1988 print '\n'.join([
2661 1989 "%install_profiles has been deprecated.",
2662 1990 "Use `ipython profile list` to view available profiles.",
2663 1991 "Requesting a profile with `ipython profile create <name>`",
2664 1992 "or `ipython --profile=<name>` will start with the bundled",
2665 1993 "profile of that name if it exists."
2666 1994 ])
2667 1995
2668 1996 @line_magic
2669 1997 def install_default_config(self, parameter_s=''):
2670 1998 """%install_default_config has been deprecated."""
2671 1999 print '\n'.join([
2672 2000 "%install_default_config has been deprecated.",
2673 2001 "Use `ipython profile create <name>` to initialize a profile",
2674 2002 "with the default config files.",
2675 2003 "Add `--reset` to overwrite already existing config files with defaults."
2676 2004 ])
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@@ -1,32 +1,33 b''
1 1 """Implementation of all the magic functions built into IPython.
2 2 """
3 3 #-----------------------------------------------------------------------------
4 4 # Copyright (c) 2012, IPython Development Team.
5 5 #
6 6 # Distributed under the terms of the Modified BSD License.
7 7 #
8 8 # The full license is in the file COPYING.txt, distributed with this software.
9 9 #-----------------------------------------------------------------------------
10 10
11 11 #-----------------------------------------------------------------------------
12 12 # Imports
13 13 #-----------------------------------------------------------------------------
14 14
15 15 from IPython.core.magic import Magics, register_magics
16 16 from .basic import BasicMagics
17 17 from .code import CodeMagics, MacroToEdit
18 18 from .config import ConfigMagics
19 19 from .history import HistoryMagics
20 from .namespace import NamespaceMagics
20 21
21 22 #-----------------------------------------------------------------------------
22 23 # Magic implementation classes
23 24 #-----------------------------------------------------------------------------
24 25
25 26 @register_magics
26 27 class UserMagics(Magics):
27 28 """Placeholder for user-defined magics to be added at runtime.
28 29
29 30 All magics are eventually merged into a single namespace at runtime, but we
30 31 use this class to isolate the magics defined dynamically by the user into
31 32 their own class.
32 33 """
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