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ipython.rst: cleanup, add new chapters (extension api, string lists, sh profile, ipy_user_conf.py), remove some obsolete stuff
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1 1 .. IPython documentation master file, created by sphinx-quickstart.py on Mon Mar 24 17:01:34 2008.
2 2 You can adapt this file completely to your liking, but it should at least
3 3 contain the root 'toctree' directive.
4 4
5 5 Welcome to IPython's documentation!
6 6 ===================================
7 7
8 8 Contents:
9 9
10 10 .. toctree::
11 11 :maxdepth: 2
12 12
13 13 Indices and tables
14 14 ==================
15 15
16 16 * :ref:`genindex`
17 17 * :ref:`modindex`
18 18 * :ref:`search`
19 19
20 20 Overview
21 21 ========
22 22
23 23 One of Python's most useful features is its interactive interpreter.
24 24 This system allows very fast testing of ideas without the overhead of
25 25 creating test files as is typical in most programming languages.
26 26 However, the interpreter supplied with the standard Python distribution
27 27 is somewhat limited for extended interactive use.
28 28
29 29 IPython is a free software project (released under the BSD license)
30 30 which tries to:
31 31
32 32 1. Provide an interactive shell superior to Python's default. IPython
33 33 has many features for object introspection, system shell access,
34 34 and its own special command system for adding functionality when
35 35 working interactively. It tries to be a very efficient environment
36 36 both for Python code development and for exploration of problems
37 37 using Python objects (in situations like data analysis).
38 38 2. Serve as an embeddable, ready to use interpreter for your own
39 39 programs. IPython can be started with a single call from inside
40 40 another program, providing access to the current namespace. This
41 41 can be very useful both for debugging purposes and for situations
42 42 where a blend of batch-processing and interactive exploration are
43 43 needed.
44 44 3. Offer a flexible framework which can be used as the base
45 45 environment for other systems with Python as the underlying
46 46 language. Specifically scientific environments like Mathematica,
47 47 IDL and Matlab inspired its design, but similar ideas can be
48 48 useful in many fields.
49 49 4. Allow interactive testing of threaded graphical toolkits. IPython
50 50 has support for interactive, non-blocking control of GTK, Qt and
51 51 WX applications via special threading flags. The normal Python
52 52 shell can only do this for Tkinter applications.
53 53
54 54
55 Main features
56
57 * Dynamic object introspection. One can access docstrings, function
58 definition prototypes, source code, source files and other details
59 of any object accessible to the interpreter with a single
60 keystroke ('?', and using '??' provides additional detail).
61 * Searching through modules and namespaces with '*' wildcards, both
62 when using the '?' system and via the %psearch command.
63 * Completion in the local namespace, by typing TAB at the prompt.
64 This works for keywords, methods, variables and files in the
65 current directory. This is supported via the readline library, and
66 full access to configuring readline's behavior is provided.
67 * Numbered input/output prompts with command history (persistent
68 across sessions and tied to each profile), full searching in this
69 history and caching of all input and output.
70 * User-extensible 'magic' commands. A set of commands prefixed with
71 % is available for controlling IPython itself and provides
72 directory control, namespace information and many aliases to
73 common system shell commands.
74 * Alias facility for defining your own system aliases.
75 * Complete system shell access. Lines starting with ! are passed
76 directly to the system shell, and using !! captures shell output
77 into python variables for further use.
78 * Background execution of Python commands in a separate thread.
79 IPython has an internal job manager called jobs, and a
80 conveninence backgrounding magic function called %bg.
81 * The ability to expand python variables when calling the system
82 shell. In a shell command, any python variable prefixed with $ is
83 expanded. A double $$ allows passing a literal $ to the shell (for
84 access to shell and environment variables like $PATH).
85 * Filesystem navigation, via a magic %cd command, along with a
86 persistent bookmark system (using %bookmark) for fast access to
87 frequently visited directories.
88 * A lightweight persistence framework via the %store command, which
89 allows you to save arbitrary Python variables. These get restored
90 automatically when your session restarts.
91 * Automatic indentation (optional) of code as you type (through the
92 readline library).
93 * Macro system for quickly re-executing multiple lines of previous
94 input with a single name. Macros can be stored persistently via
95 %store and edited via %edit.
96 * Session logging (you can then later use these logs as code in your
97 programs). Logs can optionally timestamp all input, and also store
98 session output (marked as comments, so the log remains valid
99 Python source code).
100 * Session restoring: logs can be replayed to restore a previous
101 session to the state where you left it.
102 * Verbose and colored exception traceback printouts. Easier to parse
103 visually, and in verbose mode they produce a lot of useful
104 debugging information (basically a terminal version of the cgitb
105 module).
106 * Auto-parentheses: callable objects can be executed without
107 parentheses: 'sin 3' is automatically converted to 'sin(3)'.
108 * Auto-quoting: using ',' or ';' as the first character forces
109 auto-quoting of the rest of the line: ',my_function a b' becomes
110 automatically 'my_function("a","b")', while ';my_function a b'
111 becomes 'my_function("a b")'.
112 * Extensible input syntax. You can define filters that pre-process
113 user input to simplify input in special situations. This allows
114 for example pasting multi-line code fragments which start with
115 '>>>' or '...' such as those from other python sessions or the
116 standard Python documentation.
117 * Flexible configuration system. It uses a configuration file which
118 allows permanent setting of all command-line options, module
119 loading, code and file execution. The system allows recursive file
120 inclusion, so you can have a base file with defaults and layers
121 which load other customizations for particular projects.
122 * Embeddable. You can call IPython as a python shell inside your own
123 python programs. This can be used both for debugging code or for
124 providing interactive abilities to your programs with knowledge
125 about the local namespaces (very useful in debugging and data
126 analysis situations).
127 * Easy debugger access. You can set IPython to call up an enhanced
128 version of the Python debugger (pdb) every time there is an
129 uncaught exception. This drops you inside the code which triggered
130 the exception with all the data live and it is possible to
131 navigate the stack to rapidly isolate the source of a bug. The
132 %run magic command -with the -d option- can run any script under
133 pdb's control, automatically setting initial breakpoints for you.
134 This version of pdb has IPython-specific improvements, including
135 tab-completion and traceback coloring support.
136 * Profiler support. You can run single statements (similar to
137 profile.run()) or complete programs under the profiler's control.
138 While this is possible with standard cProfile or profile modules,
139 IPython wraps this functionality with magic commands (see '%prun'
140 and '%run -p') convenient for rapid interactive work.
141 * Doctest support. The special %doctest_mode command toggles a mode
142 that allows you to paste existing doctests (with leading '>>>'
143 prompts and whitespace) and uses doctest-compatible prompts and
144 output, so you can use IPython sessions as doctest code.
55 Main features
56 -------------
57
58 * Dynamic object introspection. One can access docstrings, function
59 definition prototypes, source code, source files and other details
60 of any object accessible to the interpreter with a single
61 keystroke ('?', and using '??' provides additional detail).
62 * Searching through modules and namespaces with '*' wildcards, both
63 when using the '?' system and via the %psearch command.
64 * Completion in the local namespace, by typing TAB at the prompt.
65 This works for keywords, methods, variables and files in the
66 current directory. This is supported via the readline library, and
67 full access to configuring readline's behavior is provided.
68 * Numbered input/output prompts with command history (persistent
69 across sessions and tied to each profile), full searching in this
70 history and caching of all input and output.
71 * User-extensible 'magic' commands. A set of commands prefixed with
72 % is available for controlling IPython itself and provides
73 directory control, namespace information and many aliases to
74 common system shell commands.
75 * Alias facility for defining your own system aliases.
76 * Complete system shell access. Lines starting with ! are passed
77 directly to the system shell, and using !! captures shell output
78 into python variables for further use.
79 * Background execution of Python commands in a separate thread.
80 IPython has an internal job manager called jobs, and a
81 conveninence backgrounding magic function called %bg.
82 * The ability to expand python variables when calling the system
83 shell. In a shell command, any python variable prefixed with $ is
84 expanded. A double $$ allows passing a literal $ to the shell (for
85 access to shell and environment variables like $PATH).
86 * Filesystem navigation, via a magic %cd command, along with a
87 persistent bookmark system (using %bookmark) for fast access to
88 frequently visited directories.
89 * A lightweight persistence framework via the %store command, which
90 allows you to save arbitrary Python variables. These get restored
91 automatically when your session restarts.
92 * Automatic indentation (optional) of code as you type (through the
93 readline library).
94 * Macro system for quickly re-executing multiple lines of previous
95 input with a single name. Macros can be stored persistently via
96 %store and edited via %edit.
97 * Session logging (you can then later use these logs as code in your
98 programs). Logs can optionally timestamp all input, and also store
99 session output (marked as comments, so the log remains valid
100 Python source code).
101 * Session restoring: logs can be replayed to restore a previous
102 session to the state where you left it.
103 * Verbose and colored exception traceback printouts. Easier to parse
104 visually, and in verbose mode they produce a lot of useful
105 debugging information (basically a terminal version of the cgitb
106 module).
107 * Auto-parentheses: callable objects can be executed without
108 parentheses: 'sin 3' is automatically converted to 'sin(3)'.
109 * Auto-quoting: using ',' or ';' as the first character forces
110 auto-quoting of the rest of the line: ',my_function a b' becomes
111 automatically 'my_function("a","b")', while ';my_function a b'
112 becomes 'my_function("a b")'.
113 * Extensible input syntax. You can define filters that pre-process
114 user input to simplify input in special situations. This allows
115 for example pasting multi-line code fragments which start with
116 '>>>' or '...' such as those from other python sessions or the
117 standard Python documentation.
118 * Flexible configuration system. It uses a configuration file which
119 allows permanent setting of all command-line options, module
120 loading, code and file execution. The system allows recursive file
121 inclusion, so you can have a base file with defaults and layers
122 which load other customizations for particular projects.
123 * Embeddable. You can call IPython as a python shell inside your own
124 python programs. This can be used both for debugging code or for
125 providing interactive abilities to your programs with knowledge
126 about the local namespaces (very useful in debugging and data
127 analysis situations).
128 * Easy debugger access. You can set IPython to call up an enhanced
129 version of the Python debugger (pdb) every time there is an
130 uncaught exception. This drops you inside the code which triggered
131 the exception with all the data live and it is possible to
132 navigate the stack to rapidly isolate the source of a bug. The
133 %run magic command -with the -d option- can run any script under
134 pdb's control, automatically setting initial breakpoints for you.
135 This version of pdb has IPython-specific improvements, including
136 tab-completion and traceback coloring support.
137 * Profiler support. You can run single statements (similar to
138 profile.run()) or complete programs under the profiler's control.
139 While this is possible with standard cProfile or profile modules,
140 IPython wraps this functionality with magic commands (see '%prun'
141 and '%run -p') convenient for rapid interactive work.
142 * Doctest support. The special %doctest_mode command toggles a mode
143 that allows you to paste existing doctests (with leading '>>>'
144 prompts and whitespace) and uses doctest-compatible prompts and
145 output, so you can use IPython sessions as doctest code.
145 146
146 147
147 148 Portability and Python requirements
148 149 -----------------------------------
149 150
150 151 Python requirements: IPython requires with Python version 2.3 or newer.
151 152 If you are still using Python 2.2 and can not upgrade, the last version
152 153 of IPython which worked with Python 2.2 was 0.6.15, so you will have to
153 154 use that.
154 155
155 156 IPython is developed under Linux, but it should work in any reasonable
156 157 Unix-type system (tested OK under Solaris and the BSD family, for which
157 158 a port exists thanks to Dryice Liu).
158 159
159 160 Mac OS X: it works, apparently without any problems (thanks to Jim Boyle
160 161 at Lawrence Livermore for the information). Thanks to Andrea Riciputi,
161 162 Fink support is available.
162 163
163 164 CygWin: it works mostly OK, though some users have reported problems
164 165 with prompt coloring. No satisfactory solution to this has been found so
165 166 far, you may want to disable colors permanently in the ipythonrc
166 167 configuration file if you experience problems. If you have proper color
167 168 support under cygwin, please post to the IPython mailing list so this
168 169 issue can be resolved for all users.
169 170
170 171 Windows: it works well under Windows XP/2k, and I suspect NT should
171 172 behave similarly. Section 2.3 <node2.html#sub:Under-Windows> describes
172 173 installation details for Windows, including some additional tools needed
173 174 on this platform.
174 175
175 176 Windows 9x support is present, and has been reported to work fine (at
176 177 least on WinME).
177 178
178 179 Note, that I have very little access to and experience with Windows
179 180 development. However, an excellent group of Win32 users (led by Ville
180 181 Vainio), consistently contribute bugfixes and platform-specific
181 182 enhancements, so they more than make up for my deficiencies on that
182 183 front. In fact, Win32 users report using IPython as a system shell (see
183 184 Sec. 12 <node12.html#sec:IPython-as-shell> for details), as it offers a
184 185 level of control and features which the default cmd.exe doesn't provide.
185 186
186 187
187 188 Location
188 189 ========
189 190
190 191 IPython is generously hosted at http://ipython.scipy.org by the
191 192 Enthought, Inc and the SciPy project. This site offers downloads,
192 193 subversion access, mailing lists and a bug tracking system. I am very
193 194 grateful to Enthought (http://www.enthought.com) and all of the SciPy
194 195 team for their contribution.
195 196
196 197 Installation
197 198 ============
198 199
199 200 Instant instructions
200 201 --------------------
201 202
202 203 If you are of the impatient kind, under Linux/Unix simply untar/unzip
203 204 the download, then install with 'python setup.py install'. Under
204 205 Windows, double-click on the provided .exe binary installer.
205 206
206 207 Then, take a look at Sections 3 <node3.html#sec:good_config> for
207 208 configuring things optimally and 4 <node4.html#sec:quick_tips> for quick
208 209 tips on efficient use of IPython. You can later refer to the rest of the
209 210 manual for all the gory details.
210 211
211 212 See the notes in sec. 2.4 <#sec:upgrade> for upgrading IPython versions.
212 213
213 214
214 215 Detailed Unix instructions (Linux, Mac OS X, etc.)
215 216
216 217 For RPM based systems, simply install the supplied package in the usual
217 218 manner. If you download the tar archive, the process is:
218 219
219 220 1. Unzip/untar the ipython-XXX.tar.gz file wherever you want (XXX is
220 221 the version number). It will make a directory called ipython-XXX.
221 222 Change into that directory where you will find the files README
222 223 and setup.py. Once you've completed the installation, you can
223 224 safely remove this directory.
224 225 2. If you are installing over a previous installation of version
225 226 0.2.0 or earlier, first remove your $HOME/.ipython directory,
226 227 since the configuration file format has changed somewhat (the '='
227 228 were removed from all option specifications). Or you can call
228 229 ipython with the -upgrade option and it will do this automatically
229 230 for you.
230 231 3. IPython uses distutils, so you can install it by simply typing at
231 the system prompt (don't type the $)
232 $ python setup.py install
232 the system prompt (don't type the $)::
233
234 $ python setup.py install
235
233 236 Note that this assumes you have root access to your machine. If
234 237 you don't have root access or don't want IPython to go in the
235 default python directories, you'll need to use the |--home| option
236 (or |--prefix|). For example:
237 |$ python setup.py install --home $HOME/local|
238 default python directories, you'll need to use the ``--home`` option
239 (or ``--prefix``). For example::
240
241 $ python setup.py install --home $HOME/local
242
238 243 will install IPython into $HOME/local and its subdirectories
239 244 (creating them if necessary).
240 You can type
241 |$ python setup.py --help|
245 You can type::
246
247 $ python setup.py --help
248
242 249 for more details.
243 Note that if you change the default location for |--home| at
250
251 Note that if you change the default location for ``--home`` at
244 252 installation, IPython may end up installed at a location which is
245 253 not part of your $PYTHONPATH environment variable. In this case,
246 254 you'll need to configure this variable to include the actual
247 255 directory where the IPython/ directory ended (typically the value
248 you give to |--home| plus /lib/python).
256 you give to ``--home`` plus /lib/python).
249 257
250 258
251 259 Mac OSX information
252 260 -------------------
253 261
254 262 Under OSX, there is a choice you need to make. Apple ships its own build
255 263 of Python, which lives in the core OSX filesystem hierarchy. You can
256 264 also manually install a separate Python, either purely by hand
257 265 (typically in /usr/local) or by using Fink, which puts everything under
258 266 /sw. Which route to follow is a matter of personal preference, as I've
259 267 seen users who favor each of the approaches. Here I will simply list the
260 268 known installation issues under OSX, along with their solutions.
261 269
262 270 This page: http://geosci.uchicago.edu/~tobis/pylab.html contains
263 271 information on this topic, with additional details on how to make
264 272 IPython and matplotlib play nicely under OSX.
265 273
266 274
267 275 GUI problems
268 276 ------------
269 277
270 278 The following instructions apply to an install of IPython under OSX from
271 279 unpacking the .tar.gz distribution and installing it for the default
272 280 Python interpreter shipped by Apple. If you are using a fink install,
273 281 fink will take care of these details for you, by installing IPython
274 282 against fink's Python.
275 283
276 284 IPython offers various forms of support for interacting with graphical
277 285 applications from the command line, from simple Tk apps (which are in
278 286 principle always supported by Python) to interactive control of WX, Qt
279 287 and GTK apps. Under OSX, however, this requires that ipython is
280 288 installed by calling the special pythonw script at installation time,
281 289 which takes care of coordinating things with Apple's graphical environment.
282 290
283 So when installing under OSX, it is best to use the following command:
284 | $ sudo pythonw setup.py install --install-scripts=/usr/local/bin|
291 So when installing under OSX, it is best to use the following command::
292
293 $ sudo pythonw setup.py install --install-scripts=/usr/local/bin
294
285 295 or
286 | $ sudo pythonw setup.py install --install-scripts=/usr/bin|
296
297 $ sudo pythonw setup.py install --install-scripts=/usr/bin
298
287 299 depending on where you like to keep hand-installed executables.
288 300
289 301 The resulting script will have an appropriate shebang line (the first
290 302 line in the script whic begins with #!...) such that the ipython
291 303 interpreter can interact with the OS X GUI. If the installed version
292 304 does not work and has a shebang line that points to, for example, just
293 305 /usr/bin/python, then you might have a stale, cached version in your
294 306 build/scripts-<python-version> directory. Delete that directory and
295 307 rerun the setup.py.
296 308
297 It is also a good idea to use the special flag |--install-scripts| as
309 It is also a good idea to use the special flag ``--install-scripts`` as
298 310 indicated above, to ensure that the ipython scripts end up in a location
299 311 which is part of your $PATH. Otherwise Apple's Python will put the
300 312 scripts in an internal directory not available by default at the command
301 313 line (if you use /usr/local/bin, you need to make sure this is in your
302 314 $PATH, which may not be true by default).
303 315
304 316
305 317 Readline problems
306 318 -----------------
307 319
308 320 By default, the Python version shipped by Apple does not include the
309 321 readline library, so central to IPython's behavior. If you install
310 322 IPython against Apple's Python, you will not have arrow keys, tab
311 323 completion, etc. For Mac OSX 10.3 (Panther), you can find a prebuilt
312 324 readline library here:
313 325 http://pythonmac.org/packages/readline-5.0-py2.3-macosx10.3.zip
314 326
315 327 If you are using OSX 10.4 (Tiger), after installing this package you
316 328 need to either:
317 329
318 330 1. move readline.so from /Library/Python/2.3 to
319 331 /Library/Python/2.3/site-packages, or
320 332 2. install http://pythonmac.org/packages/TigerPython23Compat.pkg.zip
321 333
322 334 Users installing against Fink's Python or a properly hand-built one
323 335 should not have this problem.
324 336
325 337
326 338 DarwinPorts
327 339 -----------
328 340
329 341 I report here a message from an OSX user, who suggests an alternative
330 342 means of using IPython under this operating system with good results.
331 343 Please let me know of any updates that may be useful for this section.
332 344 His message is reproduced verbatim below:
333 345
334 346 From: Markus Banfi <markus.banfi-AT-mospheira.net>
335 347
336 348 As a MacOS X (10.4.2) user I prefer to install software using
337 349 DawinPorts instead of Fink. I had no problems installing ipython
338 350 with DarwinPorts. It's just:
339 351
340 352 sudo port install py-ipython
341 353
342 354 It automatically resolved all dependencies (python24, readline,
343 355 py-readline). So far I did not encounter any problems with the
344 356 DarwinPorts port of ipython.
345 357
346 358
347 359
348 360 Windows instructions
349 361 --------------------
350 362
351 363 Some of IPython's very useful features are:
352 364
353 365 * Integrated readline support (Tab-based file, object and attribute
354 366 completion, input history across sessions, editable command line,
355 367 etc.)
356 368 * Coloring of prompts, code and tracebacks.
357 369
358 370 These, by default, are only available under Unix-like operating systems.
359 371 However, thanks to Gary Bishop's work, Windows XP/2k users can also
360 372 benefit from them. His readline library originally implemented both GNU
361 373 readline functionality and color support, so that IPython under Windows
362 374 XP/2k can be as friendly and powerful as under Unix-like environments.
363 375
364 376 This library, now named PyReadline, has been absorbed by the IPython
365 377 team (Jörgen Stenarson, in particular), and it continues to be developed
366 378 with new features, as well as being distributed directly from the
367 379 IPython site.
368 380
369 381 The PyReadline extension requires CTypes and the windows IPython
370 382 installer needs PyWin32, so in all you need:
371 383
372 384 1. PyWin32 from http://sourceforge.net/projects/pywin32.
373 385 2. PyReadline for Windows from
374 386 http://ipython.scipy.org/moin/PyReadline/Intro. That page contains
375 387 further details on using and configuring the system to your liking.
376 388 3. Finally, only if you are using Python 2.3 or 2.4, you need CTypes
377 389 from http://starship.python.net/crew/theller/ctypes(you must use
378 390 version 0.9.1 or newer). This package is included in Python 2.5,
379 391 so you don't need to manually get it if your Python version is 2.5
380 392 or newer.
381 393
382 394 Warning about a broken readline-like library: several users have
383 395 reported problems stemming from using the pseudo-readline library at
384 396 http://newcenturycomputers.net/projects/readline.html. This is a broken
385 397 library which, while called readline, only implements an incomplete
386 398 subset of the readline API. Since it is still called readline, it fools
387 399 IPython's detection mechanisms and causes unpredictable crashes later.
388 400 If you wish to use IPython under Windows, you must NOT use this library,
389 401 which for all purposes is (at least as of version 1.6) terminally broken.
390 402
391 403
392 404 Installation procedure
393 405 ----------------------
394 406
395 407 Once you have the above installed, from the IPython download directory
396 408 grab the ipython-XXX.win32.exe file, where XXX represents the version
397 409 number. This is a regular windows executable installer, which you can
398 410 simply double-click to install. It will add an entry for IPython to your
399 411 Start Menu, as well as registering IPython in the Windows list of
400 412 applications, so you can later uninstall it from the Control Panel.
401 413
402 414 IPython tries to install the configuration information in a directory
403 415 named .ipython (_ipython under Windows) located in your 'home'
404 416 directory. IPython sets this directory by looking for a HOME environment
405 417 variable; if such a variable does not exist, it uses HOMEDRIVE\HOMEPATH
406 418 (these are always defined by Windows). This typically gives something
407 419 like C:\Documents and Settings\YourUserName, but your local details may
408 420 vary. In this directory you will find all the files that configure
409 421 IPython's defaults, and you can put there your profiles and extensions.
410 422 This directory is automatically added by IPython to sys.path, so
411 423 anything you place there can be found by import statements.
412 424
413 425
414 426 Upgrading
415 427 ---------
416 428
417 429 For an IPython upgrade, you should first uninstall the previous version.
418 430 This will ensure that all files and directories (such as the
419 431 documentation) which carry embedded version strings in their names are
420 432 properly removed.
421 433
422 434
423 435 Manual installation under Win32
424 436 -------------------------------
425 437
426 438 In case the automatic installer does not work for some reason, you can
427 439 download the ipython-XXX.tar.gz file, which contains the full IPython
428 440 source distribution (the popular WinZip can read .tar.gz files). After
429 441 uncompressing the archive, you can install it at a command terminal just
430 442 like any other Python module, by using 'python setup.py install'.
431 443
432 444 After the installation, run the supplied win32_manual_post_install.py
433 445 script, which creates the necessary Start Menu shortcuts for you.
434 446
435 447
436 448
437 449 Upgrading from a previous version
438 450 ---------------------------------
439 451
440 452 If you are upgrading from a previous version of IPython, after doing the
441 453 routine installation described above, you should call IPython with the
442 454 -upgrade option the first time you run your new copy. This will
443 455 automatically update your configuration directory while preserving
444 456 copies of your old files. You can then later merge back any personal
445 457 customizations you may have made into the new files. It is a good idea
446 458 to do this as there may be new options available in the new
447 459 configuration files which you will not have.
448 460
449 461 Under Windows, if you don't know how to call python scripts with
450 462 arguments from a command line, simply delete the old config directory
451 463 and IPython will make a new one. Win2k and WinXP users will find it in
452 464 C:\Documents and Settings\YourUserName\_ipython, and Win 9x users under
453 465 C:\Program Files\IPython\_ipython.
454 466
455 467 Initial configuration of your environment
456 468 =========================================
457 469
458 470 This section will help you set various things in your environment for
459 471 your IPython sessions to be as efficient as possible. All of IPython's
460 472 configuration information, along with several example files, is stored
461 473 in a directory named by default $HOME/.ipython. You can change this by
462 474 defining the environment variable IPYTHONDIR, or at runtime with the
463 475 command line option -ipythondir.
464 476
465 477 If all goes well, the first time you run IPython it should automatically
466 478 create a user copy of the config directory for you, based on its builtin
467 479 defaults. You can look at the files it creates to learn more about
468 480 configuring the system. The main file you will modify to configure
469 481 IPython's behavior is called ipythonrc (with a .ini extension under
470 482 Windows), included for reference in Sec. 7.1
471 483 <node7.html#sec:ipytonrc-sample>. This file is very commented and has
472 484 many variables you can change to suit your taste, you can find more
473 485 details in Sec. 7 <node7.html#sec:customization>. Here we discuss the
474 486 basic things you will want to make sure things are working properly from
475 487 the beginning.
476 488
477 489
478 490
479 491 Access to the Python help system
480 492 --------------------------------
481 493
482 494 This is true for Python in general (not just for IPython): you should
483 495 have an environment variable called PYTHONDOCS pointing to the directory
484 496 where your HTML Python documentation lives. In my system it's
485 497 /usr/share/doc/python-docs-2.3.4/html, check your local details or ask
486 498 your systems administrator.
487 499
488 500 This is the directory which holds the HTML version of the Python
489 501 manuals. Unfortunately it seems that different Linux distributions
490 502 package these files differently, so you may have to look around a bit.
491 503 Below I show the contents of this directory on my system for reference::
492 504
493 505 [html]> ls
494 506 about.dat acks.html dist/ ext/ index.html lib/ modindex.html
495 507 stdabout.dat tut/ about.html api/ doc/ icons/ inst/ mac/ ref/ style.css
496 508
497 509 You should really make sure this variable is correctly set so that
498 510 Python's pydoc-based help system works. It is a powerful and convenient
499 511 system with full access to the Python manuals and all modules accessible
500 512 to you.
501 513
502 514 Under Windows it seems that pydoc finds the documentation automatically,
503 515 so no extra setup appears necessary.
504 516
505 517
506 518 Editor
507 519 ------
508 520
509 521 The %edit command (and its alias %ed) will invoke the editor set in your
510 522 environment as EDITOR. If this variable is not set, it will default to
511 523 vi under Linux/Unix and to notepad under Windows. You may want to set
512 524 this variable properly and to a lightweight editor which doesn't take
513 525 too long to start (that is, something other than a new instance of
514 526 Emacs). This way you can edit multi-line code quickly and with the power
515 527 of a real editor right inside IPython.
516 528
517 529 If you are a dedicated Emacs user, you should set up the Emacs server so
518 530 that new requests are handled by the original process. This means that
519 531 almost no time is spent in handling the request (assuming an Emacs
520 532 process is already running). For this to work, you need to set your
521 533 EDITOR environment variable to 'emacsclient'. The code below, supplied
522 534 by Francois Pinard, can then be used in your .emacs file to enable the
523 535 server::
524 536
525 537 (defvar server-buffer-clients)
526 538 (when (and (fboundp 'server-start) (string-equal (getenv "TERM") 'xterm))
527 539 (server-start)
528 540 (defun fp-kill-server-with-buffer-routine ()
529 541 (and server-buffer-clients (server-done)))
530 542 (add-hook 'kill-buffer-hook 'fp-kill-server-with-buffer-routine))
531 543
532 544 You can also set the value of this editor via the commmand-line option
533 545 '-editor' or in your ipythonrc file. This is useful if you wish to use
534 546 specifically for IPython an editor different from your typical default
535 547 (and for Windows users who tend to use fewer environment variables).
536 548
537 549
538 550 Color
539 551 -----
540 552
541 553 The default IPython configuration has most bells and whistles turned on
542 554 (they're pretty safe). But there's one that may cause problems on some
543 555 systems: the use of color on screen for displaying information. This is
544 556 very useful, since IPython can show prompts and exception tracebacks
545 557 with various colors, display syntax-highlighted source code, and in
546 558 general make it easier to visually parse information.
547 559
548 560 The following terminals seem to handle the color sequences fine:
549 561
550 562 * Linux main text console, KDE Konsole, Gnome Terminal, E-term,
551 563 rxvt, xterm.
552 564 * CDE terminal (tested under Solaris). This one boldfaces light colors.
553 565 * (X)Emacs buffers. See sec.3.4 <#sec:emacs> for more details on
554 566 using IPython with (X)Emacs.
555 567 * A Windows (XP/2k) command prompt with Gary Bishop's support
556 568 extensions. Gary's extensions are discussed in Sec. 2.3
557 569 <node2.html#sub:Under-Windows>.
558 570 * A Windows (XP/2k) CygWin shell. Although some users have reported
559 571 problems; it is not clear whether there is an issue for everyone
560 572 or only under specific configurations. If you have full color
561 573 support under cygwin, please post to the IPython mailing list so
562 574 this issue can be resolved for all users.
563 575
564 576 These have shown problems:
565 577
566 578 * Windows command prompt in WinXP/2k logged into a Linux machine via
567 579 telnet or ssh.
568 580 * Windows native command prompt in WinXP/2k, without Gary Bishop's
569 581 extensions. Once Gary's readline library is installed, the normal
570 582 WinXP/2k command prompt works perfectly.
571 583
572 584 Currently the following color schemes are available:
573 585
574 586 * NoColor: uses no color escapes at all (all escapes are empty '' ''
575 587 strings). This 'scheme' is thus fully safe to use in any terminal.
576 588 * Linux: works well in Linux console type environments: dark
577 589 background with light fonts. It uses bright colors for
578 590 information, so it is difficult to read if you have a light
579 591 colored background.
580 592 * LightBG: the basic colors are similar to those in the Linux scheme
581 593 but darker. It is easy to read in terminals with light backgrounds.
582 594
583 595 IPython uses colors for two main groups of things: prompts and
584 596 tracebacks which are directly printed to the terminal, and the object
585 597 introspection system which passes large sets of data through a pager.
586 598
587 599
588 600 Input/Output prompts and exception tracebacks
589 601 ---------------------------------------------
590 602
591 603 You can test whether the colored prompts and tracebacks work on your
592 604 system interactively by typing '%colors Linux' at the prompt (use
593 605 '%colors LightBG' if your terminal has a light background). If the input
594 prompt shows garbage like:
595 [0;32mIn [[1;32m1[0;32m]: [0;00m
596 instead of (in color) something like:
597 In [1]:
606 prompt shows garbage like::
607
608 [0;32mIn [[1;32m1[0;32m]: [0;00m
609
610 instead of (in color) something like::
611
612 In [1]:
613
598 614 this means that your terminal doesn't properly handle color escape
599 615 sequences. You can go to a 'no color' mode by typing '%colors NoColor'.
600 616
601 617 You can try using a different terminal emulator program (Emacs users,
602 618 see below). To permanently set your color preferences, edit the file
603 619 $HOME/.ipython/ipythonrc and set the colors option to the desired value.
604 620
605 621
606 622 Object details (types, docstrings, source code, etc.)
607 623 -----------------------------------------------------
608 624
609 625 IPython has a set of special functions for studying the objects you are
610 626 working with, discussed in detail in Sec. 6.4
611 627 <node6.html#sec:dyn-object-info>. But this system relies on passing
612 628 information which is longer than your screen through a data pager, such
613 629 as the common Unix less and more programs. In order to be able to see
614 630 this information in color, your pager needs to be properly configured. I
615 631 strongly recommend using less instead of more, as it seems that more
616 632 simply can not understand colored text correctly.
617 633
618 634 In order to configure less as your default pager, do the following:
619 635
620 636 1. Set the environment PAGER variable to less.
621 637 2. Set the environment LESS variable to -r (plus any other options
622 638 you always want to pass to less by default). This tells less to
623 639 properly interpret control sequences, which is how color
624 640 information is given to your terminal.
625 641
626 642 For the csh or tcsh shells, add to your ~/.cshrc file the lines::
627 643
628 644 setenv PAGER less
629 645 setenv LESS -r
630 646
631 647 There is similar syntax for other Unix shells, look at your system
632 648 documentation for details.
633 649
634 650 If you are on a system which lacks proper data pagers (such as Windows),
635 651 IPython will use a very limited builtin pager.
636 652
637 653 (X)Emacs configuration
638 654 ----------------------
639 655
640 656 Thanks to the work of Alexander Schmolck and Prabhu Ramachandran,
641 657 currently (X)Emacs and IPython get along very well.
642 658
643 659 Important note: You will need to use a recent enough version of
644 660 python-mode.el, along with the file ipython.el. You can check that the
645 661 version you have of python-mode.el is new enough by either looking at
646 662 the revision number in the file itself, or asking for it in (X)Emacs via
647 663 M-x py-version. Versions 4.68 and newer contain the necessary fixes for
648 664 proper IPython support.
649 665
650 666 The file ipython.el is included with the IPython distribution, in the
651 667 documentation directory (where this manual resides in PDF and HTML
652 668 formats).
653 669
654 670 Once you put these files in your Emacs path, all you need in your .emacs
655 671 file is::
656 672
657 673 (require 'ipython)
658 674
659 675 This should give you full support for executing code snippets via
660 676 IPython, opening IPython as your Python shell via C-c !, etc.
661 677
662 678 If you happen to get garbage instead of colored prompts as described in
663 679 the previous section, you may need to set also in your .emacs file::
664 680
665 681 (setq ansi-color-for-comint-mode t)
666 682
667 683
668 Notes::
684 Notes:
669 685
670 686 * There is one caveat you should be aware of: you must start the
671 687 IPython shell before attempting to execute any code regions via
672 C-c |. Simply type C-c ! to start IPython before passing any code
688 ``C-c |``. Simply type C-c ! to start IPython before passing any code
673 689 regions to the interpreter, and you shouldn't experience any
674 690 problems.
675 691 This is due to a bug in Python itself, which has been fixed for
676 692 Python 2.3, but exists as of Python 2.2.2 (reported as SF bug [
677 693 737947 ]).
678 694 * The (X)Emacs support is maintained by Alexander Schmolck, so all
679 695 comments/requests should be directed to him through the IPython
680 696 mailing lists.
681 697 * This code is still somewhat experimental so it's a bit rough
682 698 around the edges (although in practice, it works quite well).
683 699 * Be aware that if you customize py-python-command previously, this
684 700 value will override what ipython.el does (because loading the
685 701 customization variables comes later).
686 702
687 703 Quick tips
688 704 ==========
689 705
690 706 IPython can be used as an improved replacement for the Python prompt,
691 707 and for that you don't really need to read any more of this manual. But
692 708 in this section we'll try to summarize a few tips on how to make the
693 709 most effective use of it for everyday Python development, highlighting
694 710 things you might miss in the rest of the manual (which is getting long).
695 711 We'll give references to parts in the manual which provide more detail
696 712 when appropriate.
697 713
698 714 The following article by Jeremy Jones provides an introductory tutorial
699 715 about IPython:
700 716 http://www.onlamp.com/pub/a/python/2005/01/27/ipython.html
701 717
702 718 * The TAB key. TAB-completion, especially for attributes, is a
703 719 convenient way to explore the structure of any object you're
704 720 dealing with. Simply type object_name.<TAB> and a list of the
705 721 object's attributes will be printed (see sec. 6.5
706 722 <node6.html#sec:readline> for more). Tab completion also works on
707 723 file and directory names, which combined with IPython's alias
708 724 system allows you to do from within IPython many of the things you
709 725 normally would need the system shell for.
710 726 * Explore your objects. Typing object_name? will print all sorts of
711 727 details about any object, including docstrings, function
712 728 definition lines (for call arguments) and constructor details for
713 729 classes. The magic commands %pdoc, %pdef, %psource and %pfile will
714 730 respectively print the docstring, function definition line, full
715 731 source code and the complete file for any object (when they can be
716 732 found). If automagic is on (it is by default), you don't need to
717 733 type the '%' explicitly. See sec. 6.4
718 734 <node6.html#sec:dyn-object-info> for more.
719 735 * The %run magic command allows you to run any python script and
720 736 load all of its data directly into the interactive namespace.
721 737 Since the file is re-read from disk each time, changes you make to
722 738 it are reflected immediately (in contrast to the behavior of
723 739 import). I rarely use import for code I am testing, relying on
724 740 %run instead. See sec. 6.2 <node6.html#sec:magic> for more on this
725 741 and other magic commands, or type the name of any magic command
726 742 and ? to get details on it. See also sec. 6.9
727 743 <node6.html#sec:dreload> for a recursive reload command.
728 744 %run also has special flags for timing the execution of your
729 745 scripts (-t) and for executing them under the control of either
730 746 Python's pdb debugger (-d) or profiler (-p). With all of these,
731 747 %run can be used as the main tool for efficient interactive
732 748 development of code which you write in your editor of choice.
733 749 * Use the Python debugger, pdb^2 <footnode.html#foot360>. The %pdb
734 750 command allows you to toggle on and off the automatic invocation
735 751 of an IPython-enhanced pdb debugger (with coloring, tab completion
736 752 and more) at any uncaught exception. The advantage of this is that
737 753 pdb starts inside the function where the exception occurred, with
738 754 all data still available. You can print variables, see code,
739 755 execute statements and even walk up and down the call stack to
740 756 track down the true source of the problem (which often is many
741 757 layers in the stack above where the exception gets triggered).
742 758 Running programs with %run and pdb active can be an efficient to
743 759 develop and debug code, in many cases eliminating the need for
744 760 print statements or external debugging tools. I often simply put a
745 761 1/0 in a place where I want to take a look so that pdb gets
746 762 called, quickly view whatever variables I need to or test various
747 763 pieces of code and then remove the 1/0.
748 764 Note also that '%run -d' activates pdb and automatically sets
749 765 initial breakpoints for you to step through your code, watch
750 766 variables, etc. See Sec. 6.12 <node6.html#sec:cache_output> for
751 767 details.
752 768 * Use the output cache. All output results are automatically stored
753 769 in a global dictionary named Out and variables named _1, _2, etc.
754 770 alias them. For example, the result of input line 4 is available
755 771 either as Out[4] or as _4. Additionally, three variables named _,
756 772 __ and ___ are always kept updated with the for the last three
757 773 results. This allows you to recall any previous result and further
758 774 use it for new calculations. See Sec. 6.12
759 775 <node6.html#sec:cache_output> for more.
760 776 * Put a ';' at the end of a line to supress the printing of output.
761 777 This is useful when doing calculations which generate long output
762 778 you are not interested in seeing. The _* variables and the Out[]
763 779 list do get updated with the contents of the output, even if it is
764 780 not printed. You can thus still access the generated results this
765 781 way for further processing.
766 782 * A similar system exists for caching input. All input is stored in
767 783 a global list called In , so you can re-execute lines 22 through
768 784 28 plus line 34 by typing 'exec In[22:29]+In[34]' (using Python
769 785 slicing notation). If you need to execute the same set of lines
770 786 often, you can assign them to a macro with the %macro function.
771 787 See sec. 6.11 <node6.html#sec:cache_input> for more.
772 788 * Use your input history. The %hist command can show you all
773 789 previous input, without line numbers if desired (option -n) so you
774 790 can directly copy and paste code either back in IPython or in a
775 791 text editor. You can also save all your history by turning on
776 792 logging via %logstart; these logs can later be either reloaded as
777 793 IPython sessions or used as code for your programs.
778 794 * Define your own system aliases. Even though IPython gives you
779 795 access to your system shell via the ! prefix, it is convenient to
780 796 have aliases to the system commands you use most often. This
781 797 allows you to work seamlessly from inside IPython with the same
782 798 commands you are used to in your system shell.
783 799 IPython comes with some pre-defined aliases and a complete system
784 800 for changing directories, both via a stack (see %pushd, %popd and
785 801 %dhist) and via direct %cd. The latter keeps a history of visited
786 802 directories and allows you to go to any previously visited one.
787 803 * Use Python to manipulate the results of system commands. The '!!'
788 804 special syntax, and the %sc and %sx magic commands allow you to
789 805 capture system output into Python variables.
790 806 * Expand python variables when calling the shell (either via '!' and
791 807 '!!' or via aliases) by prepending a $ in front of them. You can
792 808 also expand complete python expressions. See sec. 6.7
793 809 <node6.html#sub:System-shell-access> for more.
794 810 * Use profiles to maintain different configurations (modules to
795 811 load, function definitions, option settings) for particular tasks.
796 812 You can then have customized versions of IPython for specific
797 813 purposes. See sec. 7.3 <node7.html#sec:profiles> for more.
798 814 * Embed IPython in your programs. A few lines of code are enough to
799 815 load a complete IPython inside your own programs, giving you the
800 816 ability to work with your data interactively after automatic
801 817 processing has been completed. See sec. 9 <node9.html#sec:embed>
802 818 for more.
803 819 * Use the Python profiler. When dealing with performance issues, the
804 820 %run command with a -p option allows you to run complete programs
805 821 under the control of the Python profiler. The %prun command does a
806 822 similar job for single Python expressions (like function calls).
807 823 * Use the IPython.demo.Demo class to load any Python script as an
808 824 interactive demo. With a minimal amount of simple markup, you can
809 825 control the execution of the script, stopping as needed. See
810 826 sec. 14 <node14.html#sec:interactive-demos> for more.
811 827 * Run your doctests from within IPython for development and
812 828 debugging. The special %doctest_mode command toggles a mode where
813 829 the prompt, output and exceptions display matches as closely as
814 830 possible that of the default Python interpreter. In addition, this
815 831 mode allows you to directly paste in code that contains leading
816 832 '>>>' prompts, even if they have extra leading whitespace (as is
817 833 common in doctest files). This combined with the '%history -tn'
818 834 call to see your translated history (with these extra prompts
819 835 removed and no line numbers) allows for an easy doctest workflow,
820 836 where you can go from doctest to interactive execution to pasting
821 837 into valid Python code as needed.
822 838
823 839
824 840 Source code handling tips
825 841 -------------------------
826 842
827 843 IPython is a line-oriented program, without full control of the
828 844 terminal. Therefore, it doesn't support true multiline editing. However,
829 845 it has a number of useful tools to help you in dealing effectively with
830 846 more complex editing.
831 847
832 848 The %edit command gives a reasonable approximation of multiline editing,
833 849 by invoking your favorite editor on the spot. IPython will execute the
834 850 code you type in there as if it were typed interactively. Type %edit?
835 851 for the full details on the edit command.
836 852
837 853 If you have typed various commands during a session, which you'd like to
838 854 reuse, IPython provides you with a number of tools. Start by using %hist
839 855 to see your input history, so you can see the line numbers of all input.
840 856 Let us say that you'd like to reuse lines 10 through 20, plus lines 24
841 857 and 28. All the commands below can operate on these with the syntax::
842 858
843 859 %command 10-20 24 28
844 860
845 861 where the command given can be:
846 862
847 863 * %macro <macroname>: this stores the lines into a variable which,
848 864 when called at the prompt, re-executes the input. Macros can be
849 865 edited later using '%edit macroname', and they can be stored
850 866 persistently across sessions with '%store macroname' (the storage
851 867 system is per-profile). The combination of quick macros,
852 868 persistent storage and editing, allows you to easily refine
853 869 quick-and-dirty interactive input into permanent utilities, always
854 870 available both in IPython and as files for general reuse.
855 871 * %edit: this will open a text editor with those lines pre-loaded
856 872 for further modification. It will then execute the resulting
857 873 file's contents as if you had typed it at the prompt.
858 874 * %save <filename>: this saves the lines directly to a named file on
859 875 disk.
860 876
861 877 While %macro saves input lines into memory for interactive re-execution,
862 878 sometimes you'd like to save your input directly to a file. The %save
863 879 magic does this: its input sytnax is the same as %macro, but it saves
864 880 your input directly to a Python file. Note that the %logstart command
865 881 also saves input, but it logs all input to disk (though you can
866 882 temporarily suspend it and reactivate it with %logoff/%logon); %save
867 883 allows you to select which lines of input you need to save.
868 884
869 885
870 886 Lightweight 'version control'
871 887 -----------------------------
872 888
873 889 When you call %edit with no arguments, IPython opens an empty editor
874 890 with a temporary file, and it returns the contents of your editing
875 891 session as a string variable. Thanks to IPython's output caching
876 892 mechanism, this is automatically stored::
877 893
878 894 In [1]: %edit
879 895
880 896 IPython will make a temporary file named: /tmp/ipython_edit_yR-HCN.py
881 897
882 898 Editing... done. Executing edited code...
883 899
884 900 hello - this is a temporary file
885 901
886 902 Out[1]: "print 'hello - this is a temporary file'\n"
887 903
888 904 Now, if you call '%edit -p', IPython tries to open an editor with the
889 905 same data as the last time you used %edit. So if you haven't used %edit
890 906 in the meantime, this same contents will reopen; however, it will be
891 907 done in a new file. This means that if you make changes and you later
892 908 want to find an old version, you can always retrieve it by using its
893 909 output number, via '%edit _NN', where NN is the number of the output
894 910 prompt.
895 911
896 912 Continuing with the example above, this should illustrate this idea::
897 913
898 914 In [2]: edit -p
899 915
900 916 IPython will make a temporary file named: /tmp/ipython_edit_nA09Qk.py
901 917
902 918 Editing... done. Executing edited code...
903 919
904 920 hello - now I made some changes
905 921
906 922 Out[2]: "print 'hello - now I made some changes'\n"
907 923
908 924 In [3]: edit _1
909 925
910 926 IPython will make a temporary file named: /tmp/ipython_edit_gy6-zD.py
911 927
912 928 Editing... done. Executing edited code...
913 929
914 930 hello - this is a temporary file
915 931
916 932 IPython version control at work :)
917 933
918 934 Out[3]: "print 'hello - this is a temporary file'\nprint 'IPython version control at work :)'\n"
919 935
920 936
921 937 This section was written after a contribution by Alexander Belchenko on
922 938 the IPython user list.
923 939
924 940
925 941 Effective logging
926 942 -----------------
927 943
928 944 A very useful suggestion sent in by Robert Kern follows:
929 945
930 946 I recently happened on a nifty way to keep tidy per-project log files. I
931 947 made a profile for my project (which is called "parkfield").
932 948
933 949 include ipythonrc
934 950
935 951 # cancel earlier logfile invocation:
936 952
937 953 logfile ''
938 954
939 955 execute import time
940 956
941 957 execute __cmd = '/Users/kern/research/logfiles/parkfield-%s.log rotate'
942 958
943 959 execute __IP.magic_logstart(__cmd % time.strftime('%Y-%m-%d'))
944 960
945 961 I also added a shell alias for convenience:
946 962
947 963 alias parkfield="ipython -pylab -profile parkfield"
948 964
949 965 Now I have a nice little directory with everything I ever type in,
950 966 organized by project and date.
951 967
952 968 Contribute your own: If you have your own favorite tip on using IPython
953 969 efficiently for a certain task (especially things which can't be done in
954 970 the normal Python interpreter), don't hesitate to send it!
955 971
956 972 Command-line use
957 973 ================
958 974
959 975 You start IPython with the command::
960 976
961 977 $ ipython [options] files
962 978
963 979 If invoked with no options, it executes all the files listed in sequence
964 980 and drops you into the interpreter while still acknowledging any options
965 981 you may have set in your ipythonrc file. This behavior is different from
966 982 standard Python, which when called as python -i will only execute one
967 983 file and ignore your configuration setup.
968 984
969 985 Please note that some of the configuration options are not available at
970 986 the command line, simply because they are not practical here. Look into
971 987 your ipythonrc configuration file for details on those. This file
972 988 typically installed in the $HOME/.ipython directory. For Windows users,
973 989 $HOME resolves to C:\\Documents and Settings\\YourUserName in most
974 990 instances. In the rest of this text, we will refer to this directory as
975 991 IPYTHONDIR.
976 992
977 993
978 994 Special Threading Options
979 995
980 996 The following special options are ONLY valid at the beginning of the
981 997 command line, and not later. This is because they control the initial-
982 998 ization of ipython itself, before the normal option-handling mechanism
983 999 is active.
984 1000
985 1001 * [-gthread, -qthread, -q4thread, -wthread, -pylab:] Only one of
986 1002 these can be given, and it can only be given as the first option
987 1003 passed to IPython (it will have no effect in any other position).
988 1004 They provide threading support for the GTK, Qt (versions 3 and 4)
989 1005 and WXPython toolkits, and for the matplotlib library.
990 1006 * [ ] With any of the first four options, IPython starts running a
991 1007 separate thread for the graphical toolkit's operation, so that you
992 1008 can open and control graphical elements from within an IPython
993 1009 command line, without blocking. All four provide essentially the
994 1010 same functionality, respectively for GTK, Qt3, Qt4 and WXWidgets
995 1011 (via their Python interfaces).
996 1012 * [ ] Note that with -wthread, you can additionally use the
997 1013 -wxversion option to request a specific version of wx to be used.
998 1014 This requires that you have the wxversion Python module installed,
999 1015 which is part of recent wxPython distributions.
1000 1016 * [ ] If -pylab is given, IPython loads special support for the mat
1001 1017 plotlib library (http://matplotlib.sourceforge.net), allowing
1002 1018 interactive usage of any of its backends as defined in the user's
1003 1019 ~/.matplotlib/matplotlibrc file. It automatically activates GTK,
1004 1020 Qt or WX threading for IPyhton if the choice of matplotlib backend
1005 1021 requires it. It also modifies the %run command to correctly
1006 1022 execute (without blocking) any matplotlib-based script which calls
1007 1023 show() at the end.
1008 1024 * [-tk] The -g/q/q4/wthread options, and -pylab (if matplotlib is
1009 1025 configured to use GTK, Qt3, Qt4 or WX), will normally block Tk
1010 1026 graphical interfaces. This means that when either GTK, Qt or WX
1011 1027 threading is active, any attempt to open a Tk GUI will result in a
1012 1028 dead window, and possibly cause the Python interpreter to crash.
1013 1029 An extra option, -tk, is available to address this issue. It can
1014 1030 only be given as a second option after any of the above (-gthread,
1015 1031 -wthread or -pylab).
1016 1032 * [ ] If -tk is given, IPython will try to coordinate Tk threading
1017 1033 with GTK, Qt or WX. This is however potentially unreliable, and
1018 1034 you will have to test on your platform and Python configuration to
1019 1035 determine whether it works for you. Debian users have reported
1020 1036 success, apparently due to the fact that Debian builds all of Tcl,
1021 1037 Tk, Tkinter and Python with pthreads support. Under other Linux
1022 1038 environments (such as Fedora Core 2/3), this option has caused
1023 1039 random crashes and lockups of the Python interpreter. Under other
1024 1040 operating systems (Mac OSX and Windows), you'll need to try it to
1025 1041 find out, since currently no user reports are available.
1026 1042 * [ ] There is unfortunately no way for IPython to determine at run
1027 1043 time whether -tk will work reliably or not, so you will need to do
1028 1044 some experiments before relying on it for regular work.
1029 1045
1030 1046
1031 1047
1032 1048 Regular Options
1033 1049 ---------------
1034 1050
1035 1051 After the above threading options have been given, regular options can
1036 1052 follow in any order. All options can be abbreviated to their shortest
1037 1053 non-ambiguous form and are case-sensitive. One or two dashes can be
1038 used. Some options have an alternate short form, indicated after a |.
1054 used. Some options have an alternate short form, indicated after a ``|``.
1039 1055
1040 1056 Most options can also be set from your ipythonrc configuration file. See
1041 1057 the provided example for more details on what the options do. Options
1042 1058 given at the command line override the values set in the ipythonrc file.
1043 1059
1044 1060 All options with a [no] prepended can be specified in negated form
1045 1061 (-nooption instead of -option) to turn the feature off.
1046 1062
1047 1063 * [-help:] print a help message and exit.
1048 1064 * [-pylab:] this can only be given as the first option passed to
1049 1065 IPython (it will have no effect in any other position). It adds
1050 1066 special support for the matplotlib library
1051 1067 (http://matplotlib.sourceforge.net
1052 1068 http://matplotlib.sourceforge.net), allowing interactive usage of
1053 1069 any of its backends as defined in the user's .matplotlibrc file.
1054 1070 It automatically activates GTK or WX threading for IPyhton if the
1055 1071 choice of matplotlib backend requires it. It also modifies the
1056 1072 %run command to correctly execute (without blocking) any
1057 1073 matplotlib-based script which calls show() at the end. See Sec. 15
1058 1074 <node15.html#sec:matplotlib-support> for more details.
1059 1075 * [-autocall] <val>: Make IPython automatically call any callable
1060 1076 object even if you didn't type explicit parentheses. For example,
1061 1077 'str 43' becomes 'str(43)' automatically. The value can be '0' to
1062 1078 disable the feature, '1' for smart autocall, where it is not
1063 1079 applied if there are no more arguments on the line, and '2' for
1064 1080 full autocall, where all callable objects are automatically called
1065 1081 (even if no arguments are present). The default is '1'.
1066 1082 * [-[no]autoindent:] Turn automatic indentation on/off.
1067 1083 * [-[no]automagic:] make magic commands automatic (without needing
1068 1084 their first character to be %). Type %magic at the IPython prompt
1069 1085 for more information.
1070 1086 * [-[no]autoedit_syntax:] When a syntax error occurs after editing a
1071 1087 file, automatically open the file to the trouble causing line for
1072 1088 convenient fixing.
1073 1089 * [-[no]banner:] Print the initial information banner (default on).
1074 1090 * [-c <command>:] execute the given command string, and set sys.argv
1075 1091 to ['c']. This is similar to the -c option in the normal Python
1076 1092 interpreter.
1077 1093 * [-cache_size|cs <n>:] size of the output cache (maximum number of
1078 1094 entries to hold in memory). The default is 1000, you can change it
1079 1095 permanently in your config file. Setting it to 0 completely
1080 1096 disables the caching system, and the minimum value accepted is 20
1081 1097 (if you provide a value less than 20, it is reset to 0 and a
1082 1098 warning is issued) This limit is defined because otherwise you'll
1083 1099 spend more time re-flushing a too small cache than working.
1084 1100 * [-classic|cl:] Gives IPython a similar feel to the classic Python
1085 1101 prompt.
1086 1102 * [-colors <scheme>:] Color scheme for prompts and exception
1087 1103 reporting. Currently implemented: NoColor, Linux and LightBG.
1088 1104 * [-[no]color_info:] IPython can display information about objects
1089 1105 via a set of functions, and optionally can use colors for this,
1090 1106 syntax highlighting source code and various other elements.
1091 1107 However, because this information is passed through a pager (like
1092 1108 'less') and many pagers get confused with color codes, this option
1093 1109 is off by default. You can test it and turn it on permanently in
1094 1110 your ipythonrc file if it works for you. As a reference, the
1095 1111 'less' pager supplied with Mandrake 8.2 works ok, but that in
1096 1112 RedHat 7.2 doesn't.
1097 1113 * [ ] Test it and turn it on permanently if it works with your
1098 1114 system. The magic function %color_info allows you to toggle this
1099 1115 interactively for testing.
1100 1116 * [-[no]debug:] Show information about the loading process. Very
1101 1117 useful to pin down problems with your configuration files or to
1102 1118 get details about session restores.
1103 1119 * [-[no]deep_reload:] IPython can use the deep_reload module which
1104 1120 reloads changes in modules recursively (it replaces the reload()
1105 1121 function, so you don't need to change anything to use it).
1106 1122 deep_reload() forces a full reload of modules whose code may have
1107 1123 changed, which the default reload() function does not.
1108 1124 * [ ] When deep_reload is off, IPython will use the normal reload(),
1109 1125 but deep_reload will still be available as dreload(). This feature
1110 1126 is off by default [which means that you have both normal reload()
1111 1127 and dreload()].
1112 1128 * [-editor <name>:] Which editor to use with the %edit command. By
1113 1129 default, IPython will honor your EDITOR environment variable (if
1114 1130 not set, vi is the Unix default and notepad the Windows one).
1115 1131 Since this editor is invoked on the fly by IPython and is meant
1116 1132 for editing small code snippets, you may want to use a small,
1117 1133 lightweight editor here (in case your default EDITOR is something
1118 1134 like Emacs).
1119 1135 * [-ipythondir <name>:] name of your IPython configuration directory
1120 1136 IPYTHONDIR. This can also be specified through the environment
1121 1137 variable IPYTHONDIR.
1122 1138 * [-log|l:] generate a log file of all input. The file is named
1123 1139 ipython_log.py in your current directory (which prevents logs from
1124 1140 multiple IPython sessions from trampling each other). You can use
1125 1141 this to later restore a session by loading your logfile as a file
1126 1142 to be executed with option -logplay (see below).
1127 1143 * [-logfile|lf <name>:] specify the name of your logfile.
1128 1144 * [-logplay|lp <name>:] you can replay a previous log. For restoring
1129 1145 a session as close as possible to the state you left it in, use
1130 1146 this option (don't just run the logfile). With -logplay, IPython
1131 1147 will try to reconstruct the previous working environment in full,
1132 1148 not just execute the commands in the logfile.
1133 1149 * [ ] When a session is restored, logging is automatically turned on
1134 1150 again with the name of the logfile it was invoked with (it is read
1135 1151 from the log header). So once you've turned logging on for a
1136 1152 session, you can quit IPython and reload it as many times as you
1137 1153 want and it will continue to log its history and restore from the
1138 1154 beginning every time.
1139 1155 * [ ] Caveats: there are limitations in this option. The history
1140 1156 variables _i*,_* and _dh don't get restored properly. In the
1141 1157 future we will try to implement full session saving by writing and
1142 1158 retrieving a 'snapshot' of the memory state of IPython. But our
1143 1159 first attempts failed because of inherent limitations of Python's
1144 1160 Pickle module, so this may have to wait.
1145 1161 * [-[no]messages:] Print messages which IPython collects about its
1146 1162 startup process (default on).
1147 1163 * [-[no]pdb:] Automatically call the pdb debugger after every
1148 1164 uncaught exception. If you are used to debugging using pdb, this
1149 1165 puts you automatically inside of it after any call (either in
1150 1166 IPython or in code called by it) which triggers an exception which
1151 1167 goes uncaught.
1152 1168 * [-[no]pprint:] ipython can optionally use the pprint (pretty
1153 1169 printer) module for displaying results. pprint tends to give a
1154 1170 nicer display of nested data structures. If you like it, you can
1155 1171 turn it on permanently in your config file (default off).
1156 1172 * [-profile|p] <name>: assume that your config file is
1157 1173 ipythonrc-<name> (looks in current dir first, then in IPYTHONDIR).
1158 1174 This is a quick way to keep and load multiple config files for
1159 1175 different tasks, especially if you use the include option of
1160 1176 config files. You can keep a basic IPYTHONDIR/ipythonrc file and
1161 1177 then have other 'profiles' which include this one and load extra
1162 1178 things for particular tasks. For example:
1163 1179 * [ ] 1. $HOME/.ipython/ipythonrc : load basic things you always want.
1164 1180 * [ ] 2. $HOME/.ipython/ipythonrc-math : load (1) and basic
1165 1181 math-related modules.
1166 1182 * [ ] 3. $HOME/.ipython/ipythonrc-numeric : load (1) and Numeric and
1167 1183 plotting modules.
1168 1184 * [ ] Since it is possible to create an endless loop by having
1169 1185 circular file inclusions, IPython will stop if it reaches 15
1170 1186 recursive inclusions.
1171 1187 * [-prompt_in1|pi1 <string>:] Specify the string used for input
1172 1188 prompts. Note that if you are using numbered prompts, the number
1173 1189 is represented with a '\#' in the string. Don't forget to quote
1174 1190 strings with spaces embedded in them. Default: 'In [\#]:'.
1175 1191 Sec. 7.2 <node7.html#sec:prompts> discusses in detail all the
1176 1192 available escapes to customize your prompts.
1177 1193 * [-prompt_in2|pi2 <string>:] Similar to the previous option, but
1178 1194 used for the continuation prompts. The special sequence '\D' is
1179 1195 similar to '\#', but with all digits replaced dots (so you can
1180 1196 have your continuation prompt aligned with your input prompt).
1181 1197 Default: ' .\D.:' (note three spaces at the start for alignment
1182 1198 with 'In [\#]').
1183 1199 * [-prompt_out|po <string>:] String used for output prompts, also
1184 1200 uses numbers like prompt_in1. Default: 'Out[\#]:'
1185 1201 * [-quick:] start in bare bones mode (no config file loaded).
1186 1202 * [-rcfile <name>:] name of your IPython resource configuration
1187 1203 file. Normally IPython loads ipythonrc (from current directory) or
1188 1204 IPYTHONDIR/ipythonrc.
1189 1205 * [ ] If the loading of your config file fails, IPython starts with
1190 1206 a bare bones configuration (no modules loaded at all).
1191 1207 * [-[no]readline:] use the readline library, which is needed to
1192 1208 support name completion and command history, among other things.
1193 1209 It is enabled by default, but may cause problems for users of
1194 1210 X/Emacs in Python comint or shell buffers.
1195 1211 * [ ] Note that X/Emacs 'eterm' buffers (opened with M-x term)
1196 1212 support IPython's readline and syntax coloring fine, only 'emacs'
1197 1213 (M-x shell and C-c !) buffers do not.
1198 1214 * [-screen_length|sl <n>:] number of lines of your screen. This is
1199 1215 used to control printing of very long strings. Strings longer than
1200 this number of lines will be sent through a pager instead of
1201 directly printed.
1202 * [ ] The default value for this is 0, which means IPython will
1203 auto-detect your screen size every time it needs to print certain
1204 potentially long strings (this doesn't change the behavior of the
1205 'print' keyword, it's only triggered internally). If for some
1206 reason this isn't working well (it needs curses support), specify
1207 it yourself. Otherwise don't change the default.
1208 * [-separate_in|si <string>:] separator before input prompts.
1209 Default: '\n'
1210 * [-separate_out|so <string>:] separator before output prompts.
1211 Default: nothing.
1212 * [-separate_out2|so2 <string>:] separator after output prompts.
1213 Default: nothing.
1214 * [ ] For these three options, use the value 0 to specify no separator.
1215 * [-nosep:] shorthand for '-SeparateIn 0 -SeparateOut 0
1216 -SeparateOut2 0'. Simply removes all input/output separators.
1217 * [-upgrade:] allows you to upgrade your IPYTHONDIR configuration
1218 when you install a new version of IPython. Since new versions may
1219 include new command line options or example files, this copies
1220 updated ipythonrc-type files. However, it backs up (with a .old
1221 extension) all files which it overwrites so that you can merge
1222 back any customizations you might have in your personal files.
1223 * [-Version:] print version information and exit.
1224 * [-wxversion <string>:] Select a specific version of wxPython (used
1225 in conjunction with -wthread). Requires the wxversion module, part
1226 of recent wxPython distributions
1227 * [-xmode <modename>:] Mode for exception reporting.
1228 * [ ] Valid modes: Plain, Context and Verbose.
1229 * [ ] Plain: similar to python's normal traceback printing.
1230 * [ ] Context: prints 5 lines of context source code around each
1231 line in the traceback.
1232 * [ ] Verbose: similar to Context, but additionally prints the
1233 variables currently visible where the exception happened
1234 (shortening their strings if too long). This can potentially be
1235 very slow, if you happen to have a huge data structure whose
1236 string representation is complex to compute. Your computer may
1237 appear to freeze for a while with cpu usage at 100%. If this
1238 occurs, you can cancel the traceback with Ctrl-C (maybe hitting it
1239 more than once).
1240
1241 Interactive use
1242 ===============
1243
1244 Warning: IPython relies on the existence of a global variable called
1245 __IP which controls the shell itself. If you redefine __IP to anything,
1246 bizarre behavior will quickly occur.
1247
1248 Other than the above warning, IPython is meant to work as a drop-in
1249 replacement for the standard interactive interpreter. As such, any code
1250 which is valid python should execute normally under IPython (cases where
1251 this is not true should be reported as bugs). It does, however, offer
1252 many features which are not available at a standard python prompt. What
1253 follows is a list of these.
1254
1255
1256 Caution for Windows users
1257 -------------------------
1258
1259 Windows, unfortunately, uses the '\' character as a path separator. This
1260 is a terrible choice, because '\' also represents the escape character
1261 in most modern programming languages, including Python. For this reason,
1262 issuing many of the commands discussed below (especially magics which
1263 affect the filesystem) with '\' in them will cause strange errors.
1264
1265 A partial solution is to use instead the '/' character as a path
1266 separator, which Windows recognizes in most situations. However, in
1267 Windows commands '/' flags options, so you can not use it for the root
1268 directory. This means that paths beginning at the root must be typed in
1269 a contrived manner like:
1270 %copy \opt/foo/bar.txt \tmp
1271
1272 There is no sensible thing IPython can do to truly work around this flaw
1273 in Windows^3 <footnode.html#foot878>.
1274
1275
1276
1277 Magic command system
1278 --------------------
1279
1280 IPython will treat any line whose first character is a % as a special
1281 call to a 'magic' function. These allow you to control the behavior of
1282 IPython itself, plus a lot of system-type features. They are all
1283 prefixed with a % character, but parameters are given without
1284 parentheses or quotes.
1285
1286 Example: typing '%cd mydir' (without the quotes) changes you working
1287 directory to 'mydir', if it exists.
1288
1289 If you have 'automagic' enabled (in your ipythonrc file, via the command
1290 line option -automagic or with the %automagic function), you don't need
1291 to type in the % explicitly. IPython will scan its internal list of
1292 magic functions and call one if it exists. With automagic on you can
1293 then just type 'cd mydir' to go to directory 'mydir'. The automagic
1294 system has the lowest possible precedence in name searches, so defining
1295 an identifier with the same name as an existing magic function will
1296 shadow it for automagic use. You can still access the shadowed magic
1297 function by explicitly using the % character at the beginning of the line.
1298
1299 An example (with automagic on) should clarify all this::
1300
1301 In [1]: cd ipython # %cd is called by automagic
1302
1303 /home/fperez/ipython
1304
1305 In [2]: cd=1 # now cd is just a variable
1306
1307 In [3]: cd .. # and doesn't work as a function anymore
1308
1309 ------------------------------
1310
1311 File "<console>", line 1
1312
1313 cd ..
1314
1315 ^
1316
1317 SyntaxError: invalid syntax
1318
1319 In [4]: %cd .. # but %cd always works
1320
1321 /home/fperez
1322
1323 In [5]: del cd # if you remove the cd variable
1324
1325 In [6]: cd ipython # automagic can work again
1326
1327 /home/fperez/ipython
1328
1329 You can define your own magic functions to extend the system. The
1330 following example defines a new magic command, %impall::
1331
1332 import IPython.ipapi
1333
1334 ip = IPython.ipapi.get()
1335
1336 def doimp(self, arg):
1337
1338 ip = self.api
1339
1340 ip.ex("import %s; reload(%s); from %s import *" % (
1341
1342 arg,arg,arg)
1343
1344 )
1345
1346 ip.expose_magic('impall', doimp)
1347
1348 You can also define your own aliased names for magic functions. In your
1349 ipythonrc file, placing a line like:
1350
1351 execute __IP.magic_cl = __IP.magic_clear
1352
1353 will define %cl as a new name for %clear.
1354
1355 Type %magic for more information, including a list of all available
1356 magic functions at any time and their docstrings. You can also type
1357 %magic_function_name? (see sec. 6.4 <#sec:dyn-object-info> for
1358 information on the '?' system) to get information about any particular
1359 magic function you are interested in.
1360
1361
1362 Magic commands
1363 --------------
1364
1365 The rest of this section is automatically generated for each release
1366 from the docstrings in the IPython code. Therefore the formatting is
1367 somewhat minimal, but this method has the advantage of having
1368 information always in sync with the code.
1369
1370 A list of all the magic commands available in IPython's default
1371 installation follows. This is similar to what you'll see by simply
1372 typing %magic at the prompt, but that will also give you information
1373 about magic commands you may have added as part of your personal
1374 customizations.
1375
1376
1377 %Exit: Exit IPython without confirmation.
1378
1379
1380 %Pprint: Toggle pretty printing on/off.
1381
1382
1383 %alias: Define an alias for a system command.
1384
1385 '%alias alias_name cmd' defines 'alias_name' as an alias for 'cmd'
1386
1387 Then, typing 'alias_name params' will execute the system command 'cmd
1388 params' (from your underlying operating system).
1389
1390 Aliases have lower precedence than magic functions and Python normal
1391 variables, so if 'foo' is both a Python variable and an alias, the alias
1392 can not be executed until 'del foo' removes the Python variable.
1393
1394 You can use the %l specifier in an alias definition to represent the
1395 whole line when the alias is called. For example:
1396
1397 In [2]: alias all echo "Input in brackets: <%l>"
1398 In [3]: all hello world
1399 Input in brackets: <hello world>
1400
1401 You can also define aliases with parameters using %s specifiers (one per
1402 parameter):
1403
1404 In [1]: alias parts echo first %s second %s
1405 In [2]: %parts A B
1406 first A second B
1407 In [3]: %parts A
1408 Incorrect number of arguments: 2 expected.
1409 parts is an alias to: 'echo first %s second %s'
1410
1411 Note that %l and %s are mutually exclusive. You can only use one or the
1412 other in your aliases.
1413
1414 Aliases expand Python variables just like system calls using ! or !! do:
1415 all expressions prefixed with '$' get expanded. For details of the
1416 semantic rules, see PEP-215: http://www.python.org/peps/pep-0215.html.
1417 This is the library used by IPython for variable expansion. If you want
1418 to access a true shell variable, an extra $ is necessary to prevent its
1419 expansion by IPython:
1420
1421 In [6]: alias show echo
1422 In [7]: PATH='A Python string'
1423 In [8]: show $PATH
1424 A Python string
1425 In [9]: show $$PATH
1426 /usr/local/lf9560/bin:/usr/local/intel/compiler70/ia32/bin:...
1427
1428 You can use the alias facility to acess all of $PATH. See the %rehash
1429 and %rehashx functions, which automatically create aliases for the
1430 contents of your $PATH.
1431
1432 If called with no parameters, %alias prints the current alias table.
1433
1434
1435 %autocall: Make functions callable without having to type parentheses.
1436
1437 Usage:
1438
1439 %autocall [mode]
1440
1441 The mode can be one of: 0->Off, 1->Smart, 2->Full. If not given, the
1442 value is toggled on and off (remembering the previous state).
1443
1444 In more detail, these values mean:
1445
1446 0 -> fully disabled
1447
1448 1 -> active, but do not apply if there are no arguments on the line.
1449
1450 In this mode, you get:
1451
1452 In [1]: callable Out[1]: <built-in function callable>
1453
1454 In [2]: callable 'hello' ---> callable('hello') Out[2]: False
1455
1456 2 -> Active always. Even if no arguments are present, the callable
1457 object is called:
1458
1459 In [4]: callable ---> callable()
1460
1461 Note that even with autocall off, you can still use '/' at the start of
1462 a line to treat the first argument on the command line as a function and
1463 add parentheses to it:
1464
1465 In [8]: /str 43 ---> str(43) Out[8]: '43'
1466
1467
1468 %autoindent: Toggle autoindent on/off (if available).
1469
1470
1471 %automagic: Make magic functions callable without having to type the
1472 initial %.
1473
1474 Without argumentsl toggles on/off (when off, you must call it as
1475 %automagic, of course). With arguments it sets the value, and you can
1476 use any of (case insensitive):
1477
1478 - on,1,True: to activate
1479
1480 - off,0,False: to deactivate.
1481
1482 Note that magic functions have lowest priority, so if there's a variable
1483 whose name collides with that of a magic fn, automagic won't work for
1484 that function (you get the variable instead). However, if you delete the
1485 variable (del var), the previously shadowed magic function becomes
1486 visible to automagic again.
1487
1488
1489 %bg: Run a job in the background, in a separate thread.
1490
1491 For example,
1492
1493 %bg myfunc(x,y,z=1)
1494
1495 will execute 'myfunc(x,y,z=1)' in a background thread. As soon as the
1496 execution starts, a message will be printed indicating the job number.
1497 If your job number is 5, you can use
1498
1499 myvar = jobs.result(5) or myvar = jobs[5].result
1500
1501 to assign this result to variable 'myvar'.
1502
1503 IPython has a job manager, accessible via the 'jobs' object. You can
1504 type jobs? to get more information about it, and use jobs.<TAB> to see
1505 its attributes. All attributes not starting with an underscore are meant
1506 for public use.
1507
1508 In particular, look at the jobs.new() method, which is used to create
1509 new jobs. This magic %bg function is just a convenience wrapper around
1510 jobs.new(), for expression-based jobs. If you want to create a new job
1511 with an explicit function object and arguments, you must call jobs.new()
1512 directly.
1513
1514 The jobs.new docstring also describes in detail several important
1515 caveats associated with a thread-based model for background job
1516 execution. Type jobs.new? for details.
1517
1518 You can check the status of all jobs with jobs.status().
1519
1520 The jobs variable is set by IPython into the Python builtin namespace.
1521 If you ever declare a variable named 'jobs', you will shadow this name.
1522 You can either delete your global jobs variable to regain access to the
1523 job manager, or make a new name and assign it manually to the manager
1524 (stored in IPython's namespace). For example, to assign the job manager
1525 to the Jobs name, use:
1526
1527 Jobs = __builtins__.jobs
1528
1529
1530 %bookmark: Manage IPython's bookmark system.
1531
1532 %bookmark <name> - set bookmark to current dir %bookmark <name> <dir> -
1533 set bookmark to <dir> %bookmark -l - list all bookmarks %bookmark -d
1534 <name> - remove bookmark %bookmark -r - remove all bookmarks
1535
1536 You can later on access a bookmarked folder with: %cd -b <name> or
1537 simply '%cd <name>' if there is no directory called <name> AND there is
1538 such a bookmark defined.
1539
1540 Your bookmarks persist through IPython sessions, but they are associated
1541 with each profile.
1542
1543
1544 %cd: Change the current working directory.
1545
1546 This command automatically maintains an internal list of directories you
1547 visit during your IPython session, in the variable _dh. The command
1548 %dhist shows this history nicely formatted. You can also do 'cd -<tab>'
1549 to see directory history conveniently.
1550
1551 Usage:
1552
1553 cd 'dir': changes to directory 'dir'.
1554
1555 cd -: changes to the last visited directory.
1556
1557 cd -<n>: changes to the n-th directory in the directory history.
1558
1559 cd -b <bookmark_name>: jump to a bookmark set by %bookmark (note: cd
1560 <bookmark_name> is enough if there is no directory <bookmark_name>, but
1561 a bookmark with the name exists.) 'cd -b <tab>' allows you to
1562 tab-complete bookmark names.
1563
1564 Options:
1565
1566 -q: quiet. Do not print the working directory after the cd command is
1567 executed. By default IPython's cd command does print this directory,
1568 since the default prompts do not display path information.
1569
1570 Note that !cd doesn't work for this purpose because the shell where
1571 !command runs is immediately discarded after executing 'command'.
1572
1573
1574 %color_info: Toggle color_info.
1575
1576 The color_info configuration parameter controls whether colors are used
1577 for displaying object details (by things like %psource, %pfile or the
1578 '?' system). This function toggles this value with each call.
1579
1580 Note that unless you have a fairly recent pager (less works better than
1581 more) in your system, using colored object information displays will not
1582 work properly. Test it and see.
1583
1584
1585 %colors: Switch color scheme for prompts, info system and exception
1586 handlers.
1587
1588 Currently implemented schemes: NoColor, Linux, LightBG.
1589
1590 Color scheme names are not case-sensitive.
1591
1592
1593 %cpaste: Allows you to paste & execute a pre-formatted code block from
1594 clipboard
1595
1596 You must terminate the block with '-' (two minus-signs) alone on the
1597 line. You can also provide your own sentinel with '%paste -s %%' ('%%'
1598 is the new sentinel for this operation)
1599
1600 The block is dedented prior to execution to enable execution of method
1601 definitions. '>' and '+' characters at the beginning of a line are
1602 ignored, to allow pasting directly from e-mails or diff files. The
1603 executed block is also assigned to variable named 'pasted_block' for
1604 later editing with '%edit pasted_block'.
1605
1606 You can also pass a variable name as an argument, e.g. '%cpaste foo'.
1607 This assigns the pasted block to variable 'foo' as string, without
1608 dedenting or executing it.
1609
1610 Do not be alarmed by garbled output on Windows (it's a readline bug).
1611 Just press enter and type - (and press enter again) and the block will
1612 be what was just pasted.
1613
1614 IPython statements (magics, shell escapes) are not supported (yet).
1615
1616
1617 %debug: Activate the interactive debugger in post-mortem mode.
1618
1619 If an exception has just occurred, this lets you inspect its stack
1620 frames interactively. Note that this will always work only on the last
1621 traceback that occurred, so you must call this quickly after an
1622 exception that you wish to inspect has fired, because if another one
1623 occurs, it clobbers the previous one.
1624
1625 If you want IPython to automatically do this on every exception, see the
1626 %pdb magic for more details.
1627
1628
1629 %dhist: Print your history of visited directories.
1630
1631 %dhist -> print full history
1632 %dhist n -> print last n entries only
1633 %dhist n1 n2 -> print entries between n1 and n2 (n1 not included)
1634
1635 This history is automatically maintained by the %cd command, and always
1636 available as the global list variable _dh. You can use %cd -<n> to go to
1637 directory number <n>.
1638
1639 Note that most of time, you should view directory history by entering cd
1640 -<TAB>.
1641
1642
1643 %dirs: Return the current directory stack.
1644
1645
1646 %doctest_mode: Toggle doctest mode on and off.
1647
1648 This mode allows you to toggle the prompt behavior between normal
1649 IPython prompts and ones that are as similar to the default IPython
1650 interpreter as possible.
1651
1652 It also supports the pasting of code snippets that have leading '»>' and
1653 '...' prompts in them. This means that you can paste doctests from files
1654 or docstrings (even if they have leading whitespace), and the code will
1655 execute correctly. You can then use '%history -tn' to see the translated
1656 history without line numbers; this will give you the input after removal
1657 of all the leading prompts and whitespace, which can be pasted back into
1658 an editor.
1659
1660 With these features, you can switch into this mode easily whenever you
1661 need to do testing and changes to doctests, without having to leave your
1662 existing IPython session.
1663
1664
1665 %ed: Alias to %edit.
1666
1667
1668 %edit: Bring up an editor and execute the resulting code.
1669
1670 Usage: %edit [options] [args]
1671
1672 %edit runs IPython's editor hook. The default version of this hook is
1673 set to call the __IPYTHON__.rc.editor command. This is read from your
1674 environment variable $EDITOR. If this isn't found, it will default to vi
1675 under Linux/Unix and to notepad under Windows. See the end of this
1676 docstring for how to change the editor hook.
1677
1678 You can also set the value of this editor via the command line option
1679 '-editor' or in your ipythonrc file. This is useful if you wish to use
1680 specifically for IPython an editor different from your typical default
1681 (and for Windows users who typically don't set environment variables).
1682
1683 This command allows you to conveniently edit multi-line code right in
1684 your IPython session.
1685
1686 If called without arguments, %edit opens up an empty editor with a
1687 temporary file and will execute the contents of this file when you close
1688 it (don't forget to save it!).
1689
1690 Options:
1691
1692 -n <number>: open the editor at a specified line number. By default, the
1693 IPython editor hook uses the unix syntax 'editor +N filename', but you
1694 can configure this by providing your own modified hook if your favorite
1695 editor supports line-number specifications with a different syntax.
1696
1697 -p: this will call the editor with the same data as the previous time it
1698 was used, regardless of how long ago (in your current session) it was.
1699
1700 -r: use 'raw' input. This option only applies to input taken from the
1701 user's history. By default, the 'processed' history is used, so that
1702 magics are loaded in their transformed version to valid Python. If this
1703 option is given, the raw input as typed as the command line is used
1704 instead. When you exit the editor, it will be executed by IPython's own
1705 processor.
1706
1707 -x: do not execute the edited code immediately upon exit. This is mainly
1708 useful if you are editing programs which need to be called with command
1709 line arguments, which you can then do using %run.
1710
1711 Arguments:
1712
1713 If arguments are given, the following possibilites exist:
1714
1715 - The arguments are numbers or pairs of colon-separated numbers (like 1
1716 4:8 9). These are interpreted as lines of previous input to be loaded
1717 into the editor. The syntax is the same of the %macro command.
1718
1719 - If the argument doesn't start with a number, it is evaluated as a
1720 variable and its contents loaded into the editor. You can thus edit any
1721 string which contains python code (including the result of previous edits).
1722
1723 - If the argument is the name of an object (other than a string),
1724 IPython will try to locate the file where it was defined and open the
1725 editor at the point where it is defined. You can use '%edit function' to
1726 load an editor exactly at the point where 'function' is defined, edit it
1727 and have the file be executed automatically.
1728
1729 If the object is a macro (see %macro for details), this opens up your
1730 specified editor with a temporary file containing the macro's data. Upon
1731 exit, the macro is reloaded with the contents of the file.
1732
1733 Note: opening at an exact line is only supported under Unix, and some
1734 editors (like kedit and gedit up to Gnome 2.8) do not understand the
1735 '+NUMBER' parameter necessary for this feature. Good editors like
1736 (X)Emacs, vi, jed, pico and joe all do.
1737
1738 - If the argument is not found as a variable, IPython will look for a
1739 file with that name (adding .py if necessary) and load it into the
1740 editor. It will execute its contents with execfile() when you exit,
1741 loading any code in the file into your interactive namespace.
1742
1743 After executing your code, %edit will return as output the code you
1744 typed in the editor (except when it was an existing file). This way you
1745 can reload the code in further invocations of %edit as a variable, via
1746 _<NUMBER> or Out[<NUMBER>], where <NUMBER> is the prompt number of the
1747 output.
1748
1749 Note that %edit is also available through the alias %ed.
1750
1751 This is an example of creating a simple function inside the editor and
1752 then modifying it. First, start up the editor::
1753
1754 In [1]: ed
1755 Editing... done. Executing edited code...
1756 Out[1]: 'def foo():\n print "foo() was defined in an editing session"\n'
1757
1758 We can then call the function foo():
1759
1760 In [2]: foo()
1761 foo() was defined in an editing session
1762
1763 Now we edit foo. IPython automatically loads the editor with the
1764 (temporary) file where foo() was previously defined:
1765
1766 In [3]: ed foo
1767 Editing... done. Executing edited code...
1768
1769 And if we call foo() again we get the modified version:
1770
1771 In [4]: foo()
1772 foo() has now been changed!
1773
1774 Here is an example of how to edit a code snippet successive times. First
1775 we call the editor:
1776
1777 In [8]: ed
1778 Editing... done. Executing edited code...
1779 hello
1780 Out[8]: "print 'hello'\n"
1781
1782 Now we call it again with the previous output (stored in _):
1783
1784 In [9]: ed _
1785 Editing... done. Executing edited code...
1786 hello world
1787 Out[9]: "print 'hello world'\n"
1788
1789 Now we call it with the output #8 (stored in _8, also as Out[8]):
1790
1791 In [10]: ed _8
1792 Editing... done. Executing edited code...
1793 hello again
1794 Out[10]: "print 'hello again'\n"
1795
1796 Changing the default editor hook:
1797
1798 If you wish to write your own editor hook, you can put it in a
1799 configuration file which you load at startup time. The default hook is
1800 defined in the IPython.hooks module, and you can use that as a starting
1801 example for further modifications. That file also has general
1802 instructions on how to set a new hook for use once you've defined it.
1803
1804
1805 %env: List environment variables.
1806
1807
1808 %exit: Exit IPython, confirming if configured to do so.
1809
1810 You can configure whether IPython asks for confirmation upon exit by
1811 setting the confirm_exit flag in the ipythonrc file.
1812
1813
1814 %logoff: Temporarily stop logging.
1815
1816 You must have previously started logging.
1817
1818
1819 %logon: Restart logging.
1820
1821 This function is for restarting logging which you've temporarily stopped
1822 with %logoff. For starting logging for the first time, you must use the
1823 %logstart function, which allows you to specify an optional log filename.
1824
1825
1826 %logstart: Start logging anywhere in a session.
1827
1828 %logstart [-o|-r|-t] [log_name [log_mode]]
1829
1830 If no name is given, it defaults to a file named 'ipython_log.py' in
1831 your current directory, in 'rotate' mode (see below).
1832
1833 '%logstart name' saves to file 'name' in 'backup' mode. It saves your
1834 history up to that point and then continues logging.
1835
1836 %logstart takes a second optional parameter: logging mode. This can be
1837 one of (note that the modes are given unquoted):
1838 append: well, that says it.
1839 backup: rename (if exists) to name and start name.
1840 global: single logfile in your home dir, appended to.
1841 over : overwrite existing log.
1842 rotate: create rotating logs name.1 , name.2 , etc.
1843
1844 Options:
1845
1846 -o: log also IPython's output. In this mode, all commands which generate
1847 an Out[NN] prompt are recorded to the logfile, right after their
1848 corresponding input line. The output lines are always prepended with a
1849 '#[Out]# ' marker, so that the log remains valid Python code.
1850
1851 Since this marker is always the same, filtering only the output from a
1852 log is very easy, using for example a simple awk call:
1853
1854 awk -F'#
1855
1856 \begin{displaymath}Out\end{displaymath}
1857
1858 # ' 'if($2) print $2' ipython_log.py
1859
1860 -r: log 'raw' input. Normally, IPython's logs contain the processed
1861 input, so that user lines are logged in their final form, converted into
1862 valid Python. For example, %Exit is logged as '_ip.magic("Exit"). If the
1863 -r flag is given, all input is logged exactly as typed, with no
1864 transformations applied.
1865
1866 -t: put timestamps before each input line logged (these are put in
1867 comments).
1868
1869
1870 %logstate: Print the status of the logging system.
1871
1872
1873 %logstop: Fully stop logging and close log file.
1874
1875 In order to start logging again, a new %logstart call needs to be made,
1876 possibly (though not necessarily) with a new filename, mode and other
1877 options.
1878
1879
1880 %lsmagic: List currently available magic functions.
1881
1882
1883 %macro: Define a set of input lines as a macro for future re-execution.
1884
1885 Usage:
1886 %macro [options] name n1-n2 n3-n4 ... n5 .. n6 ...
1887
1888 Options:
1889
1890 -r: use 'raw' input. By default, the 'processed' history is used, so
1891 that magics are loaded in their transformed version to valid Python. If
1892 this option is given, the raw input as typed as the command line is used
1893 instead.
1894
1895 This will define a global variable called 'name' which is a string made
1896 of joining the slices and lines you specify (n1,n2,... numbers above)
1897 from your input history into a single string. This variable acts like an
1898 automatic function which re-executes those lines as if you had typed
1899 them. You just type 'name' at the prompt and the code executes.
1900
1901 The notation for indicating number ranges is: n1-n2 means 'use line
1902 numbers n1,...n2' (the endpoint is included). That is, '5-7' means using
1903 the lines numbered 5,6 and 7.
1904
1905 Note: as a 'hidden' feature, you can also use traditional python slice
1906 notation, where N:M means numbers N through M-1.
1907
1908 For example, if your history contains (%hist prints it):
1909
1910 44: x=1
1911 45: y=3
1912 46: z=x+y
1913 47: print x
1914 48: a=5
1915 49: print 'x',x,'y',y
1916
1917 you can create a macro with lines 44 through 47 (included) and line 49
1918 called my_macro with:
1919
1920 In [51]: %macro my_macro 44-47 49
1921
1922 Now, typing 'my_macro' (without quotes) will re-execute all this code in
1923 one pass.
1924
1925 You don't need to give the line-numbers in order, and any given line
1926 number can appear multiple times. You can assemble macros with any lines
1927 from your input history in any order.
1928
1929 The macro is a simple object which holds its value in an attribute, but
1930 IPython's display system checks for macros and executes them as code
1931 instead of printing them when you type their name.
1932
1933 You can view a macro's contents by explicitly printing it with:
1934
1935 'print macro_name'.
1936
1937 For one-off cases which DON'T contain magic function calls in them you
1938 can obtain similar results by explicitly executing slices from your
1939 input history with:
1940
1941 In [60]: exec In[44:48]+In[49]
1942
1943
1944 %magic: Print information about the magic function system.
1945
1946
1947 %page: Pretty print the object and display it through a pager.
1948
1949 %page [options] OBJECT
1950
1951 If no object is given, use _ (last output).
1952
1953 Options:
1954
1955 -r: page str(object), don't pretty-print it.
1956
1957
1958 %pdb: Control the automatic calling of the pdb interactive debugger.
1959
1960 Call as '%pdb on', '%pdb 1', '%pdb off' or '%pdb 0'. If called without
1961 argument it works as a toggle.
1962
1963 When an exception is triggered, IPython can optionally call the
1964 interactive pdb debugger after the traceback printout. %pdb toggles this
1965 feature on and off.
1966
1967 The initial state of this feature is set in your ipythonrc configuration
1968 file (the variable is called 'pdb').
1969
1970 If you want to just activate the debugger AFTER an exception has fired,
1971 without having to type '%pdb on' and rerunning your code, you can use
1972 the %debug magic.
1973
1974
1975 %pdef: Print the definition header for any callable object.
1976
1977 If the object is a class, print the constructor information.
1978
1979
1980 %pdoc: Print the docstring for an object.
1981
1982 If the given object is a class, it will print both the class and the
1983 constructor docstrings.
1984
1985
1986 %pfile: Print (or run through pager) the file where an object is defined.
1987
1988 The file opens at the line where the object definition begins. IPython
1989 will honor the environment variable PAGER if set, and otherwise will do
1990 its best to print the file in a convenient form.
1991
1992 If the given argument is not an object currently defined, IPython will
1993 try to interpret it as a filename (automatically adding a .py extension
1994 if needed). You can thus use %pfile as a syntax highlighting code viewer.
1995
1996
1997 %pinfo: Provide detailed information about an object.
1998
1999 '%pinfo object' is just a synonym for object? or ?object.
2000
2001
2002 %popd: Change to directory popped off the top of the stack.
2003
2004
2005 %profile: Print your currently active IPyhton profile.
2006
2007
2008 %prun: Run a statement through the python code profiler.
2009
2010 Usage:
2011 %prun [options] statement
2012
2013 The given statement (which doesn't require quote marks) is run via the
2014 python profiler in a manner similar to the profile.run() function.
2015 Namespaces are internally managed to work correctly; profile.run cannot
2016 be used in IPython because it makes certain assumptions about namespaces
2017 which do not hold under IPython.
2018
2019 Options:
2020
2021 -l <limit>: you can place restrictions on what or how much of the
2022 profile gets printed. The limit value can be:
2023
2024 * A string: only information for function names containing this string
2025 is printed.
2026
2027 * An integer: only these many lines are printed.
2028
2029 * A float (between 0 and 1): this fraction of the report is printed (for
2030 example, use a limit of 0.4 to see the topmost 40% only).
2031
2032 You can combine several limits with repeated use of the option. For
2033 example, '-l __init__ -l 5' will print only the topmost 5 lines of
2034 information about class constructors.
2035
2036 -r: return the pstats.Stats object generated by the profiling. This
2037 object has all the information about the profile in it, and you can
2038 later use it for further analysis or in other functions.
2039
2040 -s <key>: sort profile by given key. You can provide more than one key
2041 by using the option several times: '-s key1 -s key2 -s key3...'. The
2042 default sorting key is 'time'.
2043
2044 The following is copied verbatim from the profile documentation
2045 referenced below:
2046
2047 When more than one key is provided, additional keys are used as
2048 secondary criteria when the there is equality in all keys selected
2049 before them.
2050
2051 Abbreviations can be used for any key names, as long as the abbreviation
2052 is unambiguous. The following are the keys currently defined:
2053
2054 Valid Arg Meaning
2055 "calls" call count
2056 "cumulative" cumulative time
2057 "file" file name
2058 "module" file name
2059 "pcalls" primitive call count
2060 "line" line number
2061 "name" function name
2062 "nfl" name/file/line
2063 "stdname" standard name
2064 "time" internal time
2065
2066 Note that all sorts on statistics are in descending order (placing most
2067 time consuming items first), where as name, file, and line number
2068 searches are in ascending order (i.e., alphabetical). The subtle
2069 distinction between "nfl" and "stdname" is that the standard name is a
2070 sort of the name as printed, which means that the embedded line numbers
2071 get compared in an odd way. For example, lines 3, 20, and 40 would (if
2072 the file names were the same) appear in the string order "20" "3" and
2073 "40". In contrast, "nfl" does a numeric compare of the line numbers. In
2074 fact, sort_stats("nfl") is the same as sort_stats("name", "file", "line").
2075
2076 -T <filename>: save profile results as shown on screen to a text file.
2077 The profile is still shown on screen.
2078
2079 -D <filename>: save (via dump_stats) profile statistics to given
2080 filename. This data is in a format understod by the pstats module, and
2081 is generated by a call to the dump_stats() method of profile objects.
2082 The profile is still shown on screen.
2083
2084 If you want to run complete programs under the profiler's control, use
2085 '%run -p [prof_opts] filename.py [args to program]' where prof_opts
2086 contains profiler specific options as described here.
2087
2088 You can read the complete documentation for the profile module with:
2089 In [1]: import profile; profile.help()
2090
2091
2092 %psearch: Search for object in namespaces by wildcard.
2093
2094 %psearch [options] PATTERN [OBJECT TYPE]
2095
2096 Note: ? can be used as a synonym for %psearch, at the beginning or at
2097 the end: both a*? and ?a* are equivalent to '%psearch a*'. Still, the
2098 rest of the command line must be unchanged (options come first), so for
2099 example the following forms are equivalent
2100
2101 %psearch -i a* function -i a* function? ?-i a* function
2102
2103 Arguments:
2104
2105 PATTERN
2106
2107 where PATTERN is a string containing * as a wildcard similar to its use
2108 in a shell. The pattern is matched in all namespaces on the search path.
2109 By default objects starting with a single _ are not matched, many
2110 IPython generated objects have a single underscore. The default is case
2111 insensitive matching. Matching is also done on the attributes of objects
2112 and not only on the objects in a module.
2113
2114 [OBJECT TYPE]
2115
2116 Is the name of a python type from the types module. The name is given in
2117 lowercase without the ending type, ex. StringType is written string. By
2118 adding a type here only objects matching the given type are matched.
2119 Using all here makes the pattern match all types (this is the default).
2120
2121 Options:
2122
2123 -a: makes the pattern match even objects whose names start with a single
2124 underscore. These names are normally ommitted from the search.
2125
2126 -i/-c: make the pattern case insensitive/sensitive. If neither of these
2127 options is given, the default is read from your ipythonrc file. The
2128 option name which sets this value is 'wildcards_case_sensitive'. If this
2129 option is not specified in your ipythonrc file, IPython's internal
2130 default is to do a case sensitive search.
2131
2132 -e/-s NAMESPACE: exclude/search a given namespace. The pattern you
2133 specifiy can be searched in any of the following namespaces: 'builtin',
2134 'user', 'user_global','internal', 'alias', where 'builtin' and 'user'
2135 are the search defaults. Note that you should not use quotes when
2136 specifying namespaces.
2137
2138 'Builtin' contains the python module builtin, 'user' contains all user
2139 data, 'alias' only contain the shell aliases and no python objects,
2140 'internal' contains objects used by IPython. The 'user_global' namespace
2141 is only used by embedded IPython instances, and it contains module-level
2142 globals. You can add namespaces to the search with -s or exclude them
2143 with -e (these options can be given more than once).
2144
2145 Examples:
2146
2147 %psearch a* -> objects beginning with an a %psearch -e builtin a* ->
2148 objects NOT in the builtin space starting in a %psearch a* function ->
2149 all functions beginning with an a %psearch re.e* -> objects beginning
2150 with an e in module re %psearch r*.e* -> objects that start with e in
2151 modules starting in r %psearch r*.* string -> all strings in modules
2152 beginning with r
2153
2154 Case sensitve search:
2155
2156 %psearch -c a* list all object beginning with lower case a
2157
2158 Show objects beginning with a single _:
2159
2160 %psearch -a _* list objects beginning with a single underscore
2161
2162
2163 %psource: Print (or run through pager) the source code for an object.
2164
2165
2166 %pushd: Place the current dir on stack and change directory.
2167
2168 Usage:
2169 %pushd ['dirname']
2170
2171
2172 %pwd: Return the current working directory path.
2173
2174
2175 %pycat: Show a syntax-highlighted file through a pager.
2176
2177 This magic is similar to the cat utility, but it will assume the file to
2178 be Python source and will show it with syntax highlighting.
2179
2180
2181 %quickref: Show a quick reference sheet
2182
2183
2184 %quit: Exit IPython, confirming if configured to do so (like %exit)
2185
2186
2187 %r: Repeat previous input.
2188
2189 Note: Consider using the more powerfull %rep instead!
2190
2191 If given an argument, repeats the previous command which starts with the
2192 same string, otherwise it just repeats the previous input.
2193
2194 Shell escaped commands (with ! as first character) are not recognized by
2195 this system, only pure python code and magic commands.
2196
2197
2198 %rehashx: Update the alias table with all executable files in $PATH.
2199
2200 This version explicitly checks that every entry in $PATH is a file with
2201 execute access (os.X_OK), so it is much slower than %rehash.
2202
2203 Under Windows, it checks executability as a match agains a '|'-separated
2204 string of extensions, stored in the IPython config variable
2205 win_exec_ext. This defaults to 'exe|com|bat'.
2206
2207 This function also resets the root module cache of module completer,
2208 used on slow filesystems.
2209
2210
2211 %reset: Resets the namespace by removing all names defined by the user.
2212
2213 Input/Output history are left around in case you need them.
2214
2215
2216 %run: Run the named file inside IPython as a program.
2217
2218 Usage:
2219 %run [-n -i -t [-N<N>] -d [-b<N>] -p [profile options]] file [args]
2220
2221 Parameters after the filename are passed as command-line arguments to
2222 the program (put in sys.argv). Then, control returns to IPython's prompt.
2223
2224 This is similar to running at a system prompt:
2225 $ python file args
2226 but with the advantage of giving you IPython's tracebacks, and of
2227 loading all variables into your interactive namespace for further use
2228 (unless -p is used, see below).
2229
2230 The file is executed in a namespace initially consisting only of
2231 __name__=='__main__' and sys.argv constructed as indicated. It thus sees
2232 its environment as if it were being run as a stand-alone program (except
2233 for sharing global objects such as previously imported modules). But
2234 after execution, the IPython interactive namespace gets updated with all
2235 variables defined in the program (except for __name__ and sys.argv).
2236 This allows for very convenient loading of code for interactive work,
2237 while giving each program a 'clean sheet' to run in.
2238
2239 Options:
2240
2241 -n: __name__ is NOT set to '__main__', but to the running file's name
2242 without extension (as python does under import). This allows running
2243 scripts and reloading the definitions in them without calling code
2244 protected by an ' if __name__ == "__main__" ' clause.
2245
2246 -i: run the file in IPython's namespace instead of an empty one. This is
2247 useful if you are experimenting with code written in a text editor which
2248 depends on variables defined interactively.
2249
2250 -e: ignore sys.exit() calls or SystemExit exceptions in the script being
2251 run. This is particularly useful if IPython is being used to run
2252 unittests, which always exit with a sys.exit() call. In such cases you
2253 are interested in the output of the test results, not in seeing a
2254 traceback of the unittest module.
2255
2256 -t: print timing information at the end of the run. IPython will give
2257 you an estimated CPU time consumption for your script, which under Unix
2258 uses the resource module to avoid the wraparound problems of
2259 time.clock(). Under Unix, an estimate of time spent on system tasks is
2260 also given (for Windows platforms this is reported as 0.0).
2261
2262 If -t is given, an additional -N<N> option can be given, where <N> must
2263 be an integer indicating how many times you want the script to run. The
2264 final timing report will include total and per run results.
2265
2266 For example (testing the script uniq_stable.py):
2267
2268 In [1]: run -t uniq_stable
2269
2270 IPython CPU timings (estimated):
2271 User : 0.19597 s.
2272 System: 0.0 s.
2273
2274 In [2]: run -t -N5 uniq_stable
2275
2276 IPython CPU timings (estimated):
2277 Total runs performed: 5
2278 Times : Total Per run
2279 User : 0.910862 s, 0.1821724 s.
2280 System: 0.0 s, 0.0 s.
2281
2282 -d: run your program under the control of pdb, the Python debugger. This
2283 allows you to execute your program step by step, watch variables, etc.
2284 Internally, what IPython does is similar to calling:
2285
2286 pdb.run('execfile("YOURFILENAME")')
2287
2288 with a breakpoint set on line 1 of your file. You can change the line
2289 number for this automatic breakpoint to be <N> by using the -bN option
2290 (where N must be an integer). For example:
2291
2292 %run -d -b40 myscript
2293
2294 will set the first breakpoint at line 40 in myscript.py. Note that the
2295 first breakpoint must be set on a line which actually does something
2296 (not a comment or docstring) for it to stop execution.
2297
2298 When the pdb debugger starts, you will see a (Pdb) prompt. You must
2299 first enter 'c' (without qoutes) to start execution up to the first
2300 breakpoint.
2301
2302 Entering 'help' gives information about the use of the debugger. You can
2303 easily see pdb's full documentation with "import pdb;pdb.help()" at a
2304 prompt.
2305
2306 -p: run program under the control of the Python profiler module (which
2307 prints a detailed report of execution times, function calls, etc).
2308
2309 You can pass other options after -p which affect the behavior of the
2310 profiler itself. See the docs for %prun for details.
2311
2312 In this mode, the program's variables do NOT propagate back to the
2313 IPython interactive namespace (because they remain in the namespace
2314 where the profiler executes them).
2315
2316 Internally this triggers a call to %prun, see its documentation for
2317 details on the options available specifically for profiling.
2318
2319 There is one special usage for which the text above doesn't apply: if
2320 the filename ends with .ipy, the file is run as ipython script, just as
2321 if the commands were written on IPython prompt.
2322
2323
2324 %runlog: Run files as logs.
2325
2326 Usage:
2327 %runlog file1 file2 ...
2328
2329 Run the named files (treating them as log files) in sequence inside the
2330 interpreter, and return to the prompt. This is much slower than %run
2331 because each line is executed in a try/except block, but it allows
2332 running files with syntax errors in them.
2333
2334 Normally IPython will guess when a file is one of its own logfiles, so
2335 you can typically use %run even for logs. This shorthand allows you to
2336 force any file to be treated as a log file.
2337
2338
2339 %save: Save a set of lines to a given filename.
2340
2341 Usage:
2342 %save [options] filename n1-n2 n3-n4 ... n5 .. n6 ...
2343
2344 Options:
2345
2346 -r: use 'raw' input. By default, the 'processed' history is used, so
2347 that magics are loaded in their transformed version to valid Python. If
2348 this option is given, the raw input as typed as the command line is used
2349 instead.
2350
2351 This function uses the same syntax as %macro for line extraction, but
2352 instead of creating a macro it saves the resulting string to the
2353 filename you specify.
2354
2355 It adds a '.py' extension to the file if you don't do so yourself, and
2356 it asks for confirmation before overwriting existing files.
2357
2358
2359 %sc: Shell capture - execute a shell command and capture its output.
2360
2361 DEPRECATED. Suboptimal, retained for backwards compatibility.
2362
2363 You should use the form 'var = !command' instead. Example:
2364
2365 "%sc -l myfiles = ls " should now be written as
2366
2367 "myfiles = !ls "
2368
2369 myfiles.s, myfiles.l and myfiles.n still apply as documented below.
2370
2371 - %sc [options] varname=command
2372
2373 IPython will run the given command using commands.getoutput(), and will
2374 then update the user's interactive namespace with a variable called
2375 varname, containing the value of the call. Your command can contain
2376 shell wildcards, pipes, etc.
2377
2378 The '=' sign in the syntax is mandatory, and the variable name you
2379 supply must follow Python's standard conventions for valid names.
2380
2381 (A special format without variable name exists for internal use)
2382
2383 Options:
2384
2385 -l: list output. Split the output on newlines into a list before
2386 assigning it to the given variable. By default the output is stored as a
2387 single string.
2388
2389 -v: verbose. Print the contents of the variable.
2390
2391 In most cases you should not need to split as a list, because the
2392 returned value is a special type of string which can automatically
2393 provide its contents either as a list (split on newlines) or as a
2394 space-separated string. These are convenient, respectively, either for
2395 sequential processing or to be passed to a shell command.
2396
2397 For example:
2398
2399 # Capture into variable a In [9]: sc a=ls *py
2400
2401 # a is a string with embedded newlines In [10]: a Out[10]: 'setup.py
2402 win32_manual_post_install.py'
2403
2404 # which can be seen as a list: In [11]: a.l Out[11]: ['setup.py',
2405 'win32_manual_post_install.py']
2406
2407 # or as a whitespace-separated string: In [12]: a.s Out[12]: 'setup.py
2408 win32_manual_post_install.py'
2409
2410 # a.s is useful to pass as a single command line: In [13]: !wc -l $a.s
2411 146 setup.py 130 win32_manual_post_install.py 276 total
2412
2413 # while the list form is useful to loop over: In [14]: for f in a.l:
2414 ....: !wc -l $f ....: 146 setup.py 130 win32_manual_post_install.py
2415
2416 Similiarly, the lists returned by the -l option are also special, in the
2417 sense that you can equally invoke the .s attribute on them to
2418 automatically get a whitespace-separated string from their contents:
2419
2420 In [1]: sc -l b=ls *py
2421
2422 In [2]: b Out[2]: ['setup.py', 'win32_manual_post_install.py']
2423
2424 In [3]: b.s Out[3]: 'setup.py win32_manual_post_install.py'
2425
2426 In summary, both the lists and strings used for ouptut capture have the
2427 following special attributes:
2428
2429 .l (or .list) : value as list. .n (or .nlstr): value as
2430 newline-separated string. .s (or .spstr): value as space-separated string.
2431
2432
2433 %sx: Shell execute - run a shell command and capture its output.
2434
2435 %sx command
2436
2437 IPython will run the given command using commands.getoutput(), and
2438 return the result formatted as a list (split on '\n'). Since the output
2439 is _returned_, it will be stored in ipython's regular output cache
2440 Out[N] and in the '_N' automatic variables.
2441
2442 Notes:
2443
2444 1) If an input line begins with '!!', then %sx is automatically invoked.
2445 That is, while: !ls causes ipython to simply issue system('ls'), typing
2446 !!ls is a shorthand equivalent to: %sx ls
2447
2448 2) %sx differs from %sc in that %sx automatically splits into a list,
2449 like '%sc -l'. The reason for this is to make it as easy as possible to
2450 process line-oriented shell output via further python commands. %sc is
2451 meant to provide much finer control, but requires more typing.
2452
2453 3) Just like %sc -l, this is a list with special attributes:
2454
2455 .l (or .list) : value as list. .n (or .nlstr): value as
2456 newline-separated string. .s (or .spstr): value as whitespace-separated
2457 string.
2458
2459 This is very useful when trying to use such lists as arguments to system
2460 commands.
2461
2462
2463 %system_verbose: Set verbose printing of system calls.
2464
2465 If called without an argument, act as a toggle
2466
2467
2468 %time: Time execution of a Python statement or expression.
2469
2470 The CPU and wall clock times are printed, and the value of the
2471 expression (if any) is returned. Note that under Win32, system time is
2472 always reported as 0, since it can not be measured.
2473
2474 This function provides very basic timing functionality. In Python 2.3,
2475 the timeit module offers more control and sophistication, so this could
2476 be rewritten to use it (patches welcome).
2477
2478 Some examples:
2479
2480 In [1]: time 2**128 CPU times: user 0.00 s, sys: 0.00 s, total: 0.00 s
2481 Wall time: 0.00 Out[1]: 340282366920938463463374607431768211456L
2482
2483 In [2]: n = 1000000
2484
2485 In [3]: time sum(range(n)) CPU times: user 1.20 s, sys: 0.05 s, total:
2486 1.25 s Wall time: 1.37 Out[3]: 499999500000L
2487
2488 In [4]: time print 'hello world' hello world CPU times: user 0.00 s,
2489 sys: 0.00 s, total: 0.00 s Wall time: 0.00
2490
2491 Note that the time needed by Python to compile the given expression will
2492 be reported if it is more than 0.1s. In this example, the actual
2493 exponentiation is done by Python at compilation time, so while the
2494 expression can take a noticeable amount of time to compute, that time is
2495 purely due to the compilation:
2496
2497 In [5]: time 3**9999; CPU times: user 0.00 s, sys: 0.00 s, total: 0.00 s
2498 Wall time: 0.00 s
2499
2500 In [6]: time 3**999999; CPU times: user 0.00 s, sys: 0.00 s, total: 0.00
2501 s Wall time: 0.00 s Compiler : 0.78 s
1216 this number of lines will be sent through a pager instead of
1217 directly printed.
1218 * [ ] The default value for this is 0, which means IPython will
1219 auto-detect your screen size every time it needs to print certain
1220 potentially long strings (this doesn't change the behavior of the
1221 'print' keyword, it's only triggered internally). If for some
1222 reason this isn't working well (it needs curses support), specify
1223 it yourself. Otherwise don't change the default.
1224 * [-separate_in|si <string>:] separator before input prompts.
1225 Default: '\n'
1226 * [-separate_out|so <string>:] separator before output prompts.
1227 Default: nothing.
1228 * [-separate_out2|so2 <string>:] separator after output prompts.
1229 Default: nothing.
1230 * [ ] For these three options, use the value 0 to specify no separator.
1231 * [-nosep:] shorthand for '-SeparateIn 0 -SeparateOut 0
1232 -SeparateOut2 0'. Simply removes all input/output separators.
1233 * [-upgrade:] allows you to upgrade your IPYTHONDIR configuration
1234 when you install a new version of IPython. Since new versions may
1235 include new command line options or example files, this copies
1236 updated ipythonrc-type files. However, it backs up (with a .old
1237 extension) all files which it overwrites so that you can merge
1238 back any customizations you might have in your personal files.
1239 * [-Version:] print version information and exit.
1240 * [-wxversion <string>:] Select a specific version of wxPython (used
1241 in conjunction with -wthread). Requires the wxversion module, part
1242 of recent wxPython distributions
1243 * [-xmode <modename>:] Mode for exception reporting.
1244 * [ ] Valid modes: Plain, Context and Verbose.
1245 * [ ] Plain: similar to python's normal traceback printing.
1246 * [ ] Context: prints 5 lines of context source code around each
1247 line in the traceback.
1248 * [ ] Verbose: similar to Context, but additionally prints the
1249 variables currently visible where the exception happened
1250 (shortening their strings if too long). This can potentially be
1251 very slow, if you happen to have a huge data structure whose
1252 string representation is complex to compute. Your computer may
1253 appear to freeze for a while with cpu usage at 100%. If this
1254 occurs, you can cancel the traceback with Ctrl-C (maybe hitting it
1255 more than once).
2502 1256
1257 Interactive use
1258 ===============
2503 1259
2504 %timeit: Time execution of a Python statement or expression
1260 Warning: IPython relies on the existence of a global variable called
1261 __IP which controls the shell itself. If you redefine __IP to anything,
1262 bizarre behavior will quickly occur.
2505 1263
2506 Usage:
2507 %timeit [-n<N> -r<R> [-t|-c]] statement
1264 Other than the above warning, IPython is meant to work as a drop-in
1265 replacement for the standard interactive interpreter. As such, any code
1266 which is valid python should execute normally under IPython (cases where
1267 this is not true should be reported as bugs). It does, however, offer
1268 many features which are not available at a standard python prompt. What
1269 follows is a list of these.
2508 1270
2509 Time execution of a Python statement or expression using the timeit module.
2510 1271
2511 Options: -n<N>: execute the given statement <N> times in a loop. If this
2512 value is not given, a fitting value is chosen.
1272 Caution for Windows users
1273 -------------------------
2513 1274
2514 -r<R>: repeat the loop iteration <R> times and take the best result.
2515 Default: 3
1275 Windows, unfortunately, uses the '\' character as a path separator. This
1276 is a terrible choice, because '\' also represents the escape character
1277 in most modern programming languages, including Python. For this reason,
1278 issuing many of the commands discussed below (especially magics which
1279 affect the filesystem) with '\' in them will cause strange errors.
2516 1280
2517 -t: use time.time to measure the time, which is the default on Unix.
2518 This function measures wall time.
1281 A partial solution is to use instead the '/' character as a path
1282 separator, which Windows recognizes in most situations. However, in
1283 Windows commands '/' flags options, so you can not use it for the root
1284 directory. This means that paths beginning at the root must be typed in
1285 a contrived manner like:
1286 %copy \opt/foo/bar.txt \tmp
2519 1287
2520 -c: use time.clock to measure the time, which is the default on Windows
2521 and measures wall time. On Unix, resource.getrusage is used instead and
2522 returns the CPU user time.
1288 There is no sensible thing IPython can do to truly work around this flaw
1289 in Windows^3 <footnode.html#foot878>.
2523 1290
2524 -p<P>: use a precision of <P> digits to display the timing result.
2525 Default: 3
2526 1291
2527 Examples:
2528 In [1]: %timeit pass 10000000 loops, best of 3: 53.3 ns per loop
2529 1292
2530 In [2]: u = None
1293 Magic command system
1294 --------------------
2531 1295
2532 In [3]: %timeit u is None 10000000 loops, best of 3: 184 ns per loop
1296 IPython will treat any line whose first character is a % as a special
1297 call to a 'magic' function. These allow you to control the behavior of
1298 IPython itself, plus a lot of system-type features. They are all
1299 prefixed with a % character, but parameters are given without
1300 parentheses or quotes.
2533 1301
2534 In [4]: %timeit -r 4 u == None 1000000 loops, best of 4: 242 ns per loop
1302 Example: typing '%cd mydir' (without the quotes) changes you working
1303 directory to 'mydir', if it exists.
2535 1304
2536 In [5]: import time
1305 If you have 'automagic' enabled (in your ipythonrc file, via the command
1306 line option -automagic or with the %automagic function), you don't need
1307 to type in the % explicitly. IPython will scan its internal list of
1308 magic functions and call one if it exists. With automagic on you can
1309 then just type 'cd mydir' to go to directory 'mydir'. The automagic
1310 system has the lowest possible precedence in name searches, so defining
1311 an identifier with the same name as an existing magic function will
1312 shadow it for automagic use. You can still access the shadowed magic
1313 function by explicitly using the % character at the beginning of the line.
2537 1314
2538 In [6]: %timeit -n1 time.sleep(2) 1 loops, best of 3: 2 s per loop
1315 An example (with automagic on) should clarify all this::
2539 1316
2540 The times reported by %timeit will be slightly higher than those
2541 reported by the timeit.py script when variables are accessed. This is
2542 due to the fact that %timeit executes the statement in the namespace of
2543 the shell, compared with timeit.py, which uses a single setup statement
2544 to import function or create variables. Generally, the bias does not
2545 matter as long as results from timeit.py are not mixed with those from
2546 %timeit.
1317 In [1]: cd ipython # %cd is called by automagic
2547 1318
1319 /home/fperez/ipython
2548 1320
2549 %unalias: Remove an alias
1321 In [2]: cd=1 # now cd is just a variable
2550 1322
1323 In [3]: cd .. # and doesn't work as a function anymore
2551 1324
2552 %upgrade: Upgrade your IPython installation
1325 ------------------------------
2553 1326
2554 This will copy the config files that don't yet exist in your ipython dir
2555 from the system config dir. Use this after upgrading IPython if you
2556 don't wish to delete your .ipython dir.
1327 File "<console>", line 1
2557 1328
2558 Call with -nolegacy to get rid of ipythonrc* files (recommended for new
2559 users)
1329 cd ..
2560 1330
1331 ^
2561 1332
2562 %who: Print all interactive variables, with some minimal formatting.
1333 SyntaxError: invalid syntax
2563 1334
2564 If any arguments are given, only variables whose type matches one of
2565 these are printed. For example:
1335 In [4]: %cd .. # but %cd always works
2566 1336
2567 %who function str
1337 /home/fperez
2568 1338
2569 will only list functions and strings, excluding all other types of
2570 variables. To find the proper type names, simply use type(var) at a
2571 command line to see how python prints type names. For example:
1339 In [5]: del cd # if you remove the cd variable
2572 1340
2573 In [1]: type('hello')
2574 Out[1]: <type 'str'>
1341 In [6]: cd ipython # automagic can work again
2575 1342
2576 indicates that the type name for strings is 'str'.
1343 /home/fperez/ipython
2577 1344
2578 %who always excludes executed names loaded through your configuration
2579 file and things which are internal to IPython.
1345 You can define your own magic functions to extend the system. The
1346 following example defines a new magic command, %impall::
2580 1347
2581 This is deliberate, as typically you may load many modules and the
2582 purpose of %who is to show you only what you've manually defined.
1348 import IPython.ipapi
2583 1349
1350 ip = IPython.ipapi.get()
2584 1351
2585 %who_ls: Return a sorted list of all interactive variables.
1352 def doimp(self, arg):
2586 1353
2587 If arguments are given, only variables of types matching these arguments
2588 are returned.
1354 ip = self.api
2589 1355
1356 ip.ex("import %s; reload(%s); from %s import *" % (
2590 1357
2591 %whos: Like %who, but gives some extra information about each variable.
1358 arg,arg,arg)
2592 1359
2593 The same type filtering of %who can be applied here.
1360 )
2594 1361
2595 For all variables, the type is printed. Additionally it prints:
1362 ip.expose_magic('impall', doimp)
2596 1363
2597 - For ,[],(): their length.
1364 You can also define your own aliased names for magic functions. In your
1365 ipythonrc file, placing a line like:
2598 1366
2599 - For numpy and Numeric arrays, a summary with shape, number of
2600 elements, typecode and size in memory.
1367 execute __IP.magic_cl = __IP.magic_clear
2601 1368
2602 - Everything else: a string representation, snipping their middle if too
2603 long.
1369 will define %cl as a new name for %clear.
2604 1370
1371 Type %magic for more information, including a list of all available
1372 magic functions at any time and their docstrings. You can also type
1373 %magic_function_name? (see sec. 6.4 <#sec:dyn-object-info> for
1374 information on the '?' system) to get information about any particular
1375 magic function you are interested in.
2605 1376
2606 %xmode: Switch modes for the exception handlers.
2607 1377
2608 Valid modes: Plain, Context and Verbose.
1378 Magic commands
1379 --------------
2609 1380
2610 If called without arguments, acts as a toggle.
1381 The rest of this section is automatically generated for each release
1382 from the docstrings in the IPython code. Therefore the formatting is
1383 somewhat minimal, but this method has the advantage of having
1384 information always in sync with the code.
2611 1385
1386 A list of all the magic commands available in IPython's default
1387 installation follows. This is similar to what you'll see by simply
1388 typing %magic at the prompt, but that will also give you information
1389 about magic commands you may have added as part of your personal
1390 customizations.
2612 1391
2613 Access to the standard Python help
1392 ::
1393
1394 %Exit: Exit IPython without confirmation.
1395
1396
1397 %Pprint: Toggle pretty printing on/off.
1398
1399
1400 %alias: Define an alias for a system command.
1401
1402 '%alias alias_name cmd' defines 'alias_name' as an alias for 'cmd'
1403
1404 Then, typing 'alias_name params' will execute the system command 'cmd
1405 params' (from your underlying operating system).
1406
1407 Aliases have lower precedence than magic functions and Python normal
1408 variables, so if 'foo' is both a Python variable and an alias, the alias
1409 can not be executed until 'del foo' removes the Python variable.
1410
1411 You can use the %l specifier in an alias definition to represent the
1412 whole line when the alias is called. For example:
1413
1414 In [2]: alias all echo "Input in brackets: <%l>"
1415 In [3]: all hello world
1416 Input in brackets: <hello world>
1417
1418 You can also define aliases with parameters using %s specifiers (one per
1419 parameter):
1420
1421 In [1]: alias parts echo first %s second %s
1422 In [2]: %parts A B
1423 first A second B
1424 In [3]: %parts A
1425 Incorrect number of arguments: 2 expected.
1426 parts is an alias to: 'echo first %s second %s'
1427
1428 Note that %l and %s are mutually exclusive. You can only use one or the
1429 other in your aliases.
1430
1431 Aliases expand Python variables just like system calls using ! or !! do:
1432 all expressions prefixed with '$' get expanded. For details of the
1433 semantic rules, see PEP-215: http://www.python.org/peps/pep-0215.html.
1434 This is the library used by IPython for variable expansion. If you want
1435 to access a true shell variable, an extra $ is necessary to prevent its
1436 expansion by IPython:
1437
1438 In [6]: alias show echo
1439 In [7]: PATH='A Python string'
1440 In [8]: show $PATH
1441 A Python string
1442 In [9]: show $$PATH
1443 /usr/local/lf9560/bin:/usr/local/intel/compiler70/ia32/bin:...
1444
1445 You can use the alias facility to acess all of $PATH. See the %rehash
1446 and %rehashx functions, which automatically create aliases for the
1447 contents of your $PATH.
1448
1449 If called with no parameters, %alias prints the current alias table.
1450
1451
1452 %autocall: Make functions callable without having to type parentheses.
1453
1454 Usage:
1455
1456 %autocall [mode]
1457
1458 The mode can be one of: 0->Off, 1->Smart, 2->Full. If not given, the
1459 value is toggled on and off (remembering the previous state).
1460
1461 In more detail, these values mean:
1462
1463 0 -> fully disabled
1464
1465 1 -> active, but do not apply if there are no arguments on the line.
1466
1467 In this mode, you get:
1468
1469 In [1]: callable Out[1]: <built-in function callable>
1470
1471 In [2]: callable 'hello' ---> callable('hello') Out[2]: False
1472
1473 2 -> Active always. Even if no arguments are present, the callable
1474 object is called:
1475
1476 In [4]: callable ---> callable()
1477
1478 Note that even with autocall off, you can still use '/' at the start of
1479 a line to treat the first argument on the command line as a function and
1480 add parentheses to it:
1481
1482 In [8]: /str 43 ---> str(43) Out[8]: '43'
1483
1484
1485 %autoindent: Toggle autoindent on/off (if available).
1486
1487
1488 %automagic: Make magic functions callable without having to type the
1489 initial %.
1490
1491 Without argumentsl toggles on/off (when off, you must call it as
1492 %automagic, of course). With arguments it sets the value, and you can
1493 use any of (case insensitive):
1494
1495 - on,1,True: to activate
1496
1497 - off,0,False: to deactivate.
1498
1499 Note that magic functions have lowest priority, so if there's a variable
1500 whose name collides with that of a magic fn, automagic won't work for
1501 that function (you get the variable instead). However, if you delete the
1502 variable (del var), the previously shadowed magic function becomes
1503 visible to automagic again.
1504
1505
1506 %bg: Run a job in the background, in a separate thread.
1507
1508 For example,
1509
1510 %bg myfunc(x,y,z=1)
1511
1512 will execute 'myfunc(x,y,z=1)' in a background thread. As soon as the
1513 execution starts, a message will be printed indicating the job number.
1514 If your job number is 5, you can use
1515
1516 myvar = jobs.result(5) or myvar = jobs[5].result
1517
1518 to assign this result to variable 'myvar'.
1519
1520 IPython has a job manager, accessible via the 'jobs' object. You can
1521 type jobs? to get more information about it, and use jobs.<TAB> to see
1522 its attributes. All attributes not starting with an underscore are meant
1523 for public use.
1524
1525 In particular, look at the jobs.new() method, which is used to create
1526 new jobs. This magic %bg function is just a convenience wrapper around
1527 jobs.new(), for expression-based jobs. If you want to create a new job
1528 with an explicit function object and arguments, you must call jobs.new()
1529 directly.
1530
1531 The jobs.new docstring also describes in detail several important
1532 caveats associated with a thread-based model for background job
1533 execution. Type jobs.new? for details.
1534
1535 You can check the status of all jobs with jobs.status().
1536
1537 The jobs variable is set by IPython into the Python builtin namespace.
1538 If you ever declare a variable named 'jobs', you will shadow this name.
1539 You can either delete your global jobs variable to regain access to the
1540 job manager, or make a new name and assign it manually to the manager
1541 (stored in IPython's namespace). For example, to assign the job manager
1542 to the Jobs name, use:
1543
1544 Jobs = __builtins__.jobs
1545
1546
1547 %bookmark: Manage IPython's bookmark system.
1548
1549 %bookmark <name> - set bookmark to current dir %bookmark <name> <dir> -
1550 set bookmark to <dir> %bookmark -l - list all bookmarks %bookmark -d
1551 <name> - remove bookmark %bookmark -r - remove all bookmarks
1552
1553 You can later on access a bookmarked folder with: %cd -b <name> or
1554 simply '%cd <name>' if there is no directory called <name> AND there is
1555 such a bookmark defined.
1556
1557 Your bookmarks persist through IPython sessions, but they are associated
1558 with each profile.
1559
1560
1561 %cd: Change the current working directory.
1562
1563 This command automatically maintains an internal list of directories you
1564 visit during your IPython session, in the variable _dh. The command
1565 %dhist shows this history nicely formatted. You can also do 'cd -<tab>'
1566 to see directory history conveniently.
1567
1568 Usage:
1569
1570 cd 'dir': changes to directory 'dir'.
1571
1572 cd -: changes to the last visited directory.
1573
1574 cd -<n>: changes to the n-th directory in the directory history.
1575
1576 cd -b <bookmark_name>: jump to a bookmark set by %bookmark (note: cd
1577 <bookmark_name> is enough if there is no directory <bookmark_name>, but
1578 a bookmark with the name exists.) 'cd -b <tab>' allows you to
1579 tab-complete bookmark names.
1580
1581 Options:
1582
1583 -q: quiet. Do not print the working directory after the cd command is
1584 executed. By default IPython's cd command does print this directory,
1585 since the default prompts do not display path information.
1586
1587 Note that !cd doesn't work for this purpose because the shell where
1588 !command runs is immediately discarded after executing 'command'.
1589
1590
1591 %color_info: Toggle color_info.
1592
1593 The color_info configuration parameter controls whether colors are used
1594 for displaying object details (by things like %psource, %pfile or the
1595 '?' system). This function toggles this value with each call.
1596
1597 Note that unless you have a fairly recent pager (less works better than
1598 more) in your system, using colored object information displays will not
1599 work properly. Test it and see.
1600
1601
1602 %colors: Switch color scheme for prompts, info system and exception
1603 handlers.
1604
1605 Currently implemented schemes: NoColor, Linux, LightBG.
1606
1607 Color scheme names are not case-sensitive.
1608
1609
1610 %cpaste: Allows you to paste & execute a pre-formatted code block from
1611 clipboard
1612
1613 You must terminate the block with '-' (two minus-signs) alone on the
1614 line. You can also provide your own sentinel with '%paste -s %%' ('%%'
1615 is the new sentinel for this operation)
1616
1617 The block is dedented prior to execution to enable execution of method
1618 definitions. '>' and '+' characters at the beginning of a line are
1619 ignored, to allow pasting directly from e-mails or diff files. The
1620 executed block is also assigned to variable named 'pasted_block' for
1621 later editing with '%edit pasted_block'.
1622
1623 You can also pass a variable name as an argument, e.g. '%cpaste foo'.
1624 This assigns the pasted block to variable 'foo' as string, without
1625 dedenting or executing it.
1626
1627 Do not be alarmed by garbled output on Windows (it's a readline bug).
1628 Just press enter and type - (and press enter again) and the block will
1629 be what was just pasted.
1630
1631 IPython statements (magics, shell escapes) are not supported (yet).
1632
1633
1634 %debug: Activate the interactive debugger in post-mortem mode.
1635
1636 If an exception has just occurred, this lets you inspect its stack
1637 frames interactively. Note that this will always work only on the last
1638 traceback that occurred, so you must call this quickly after an
1639 exception that you wish to inspect has fired, because if another one
1640 occurs, it clobbers the previous one.
1641
1642 If you want IPython to automatically do this on every exception, see the
1643 %pdb magic for more details.
1644
1645
1646 %dhist: Print your history of visited directories.
1647
1648 %dhist -> print full history
1649 %dhist n -> print last n entries only
1650 %dhist n1 n2 -> print entries between n1 and n2 (n1 not included)
1651
1652 This history is automatically maintained by the %cd command, and always
1653 available as the global list variable _dh. You can use %cd -<n> to go to
1654 directory number <n>.
1655
1656 Note that most of time, you should view directory history by entering cd
1657 -<TAB>.
1658
1659
1660 %dirs: Return the current directory stack.
1661
1662
1663 %doctest_mode: Toggle doctest mode on and off.
1664
1665 This mode allows you to toggle the prompt behavior between normal
1666 IPython prompts and ones that are as similar to the default IPython
1667 interpreter as possible.
1668
1669 It also supports the pasting of code snippets that have leading '»>' and
1670 '...' prompts in them. This means that you can paste doctests from files
1671 or docstrings (even if they have leading whitespace), and the code will
1672 execute correctly. You can then use '%history -tn' to see the translated
1673 history without line numbers; this will give you the input after removal
1674 of all the leading prompts and whitespace, which can be pasted back into
1675 an editor.
1676
1677 With these features, you can switch into this mode easily whenever you
1678 need to do testing and changes to doctests, without having to leave your
1679 existing IPython session.
1680
1681
1682 %ed: Alias to %edit.
1683
1684
1685 %edit: Bring up an editor and execute the resulting code.
1686
1687 Usage: %edit [options] [args]
1688
1689 %edit runs IPython's editor hook. The default version of this hook is
1690 set to call the __IPYTHON__.rc.editor command. This is read from your
1691 environment variable $EDITOR. If this isn't found, it will default to vi
1692 under Linux/Unix and to notepad under Windows. See the end of this
1693 docstring for how to change the editor hook.
1694
1695 You can also set the value of this editor via the command line option
1696 '-editor' or in your ipythonrc file. This is useful if you wish to use
1697 specifically for IPython an editor different from your typical default
1698 (and for Windows users who typically don't set environment variables).
1699
1700 This command allows you to conveniently edit multi-line code right in
1701 your IPython session.
1702
1703 If called without arguments, %edit opens up an empty editor with a
1704 temporary file and will execute the contents of this file when you close
1705 it (don't forget to save it!).
1706
1707 Options:
1708
1709 -n <number>: open the editor at a specified line number. By default, the
1710 IPython editor hook uses the unix syntax 'editor +N filename', but you
1711 can configure this by providing your own modified hook if your favorite
1712 editor supports line-number specifications with a different syntax.
1713
1714 -p: this will call the editor with the same data as the previous time it
1715 was used, regardless of how long ago (in your current session) it was.
1716
1717 -r: use 'raw' input. This option only applies to input taken from the
1718 user's history. By default, the 'processed' history is used, so that
1719 magics are loaded in their transformed version to valid Python. If this
1720 option is given, the raw input as typed as the command line is used
1721 instead. When you exit the editor, it will be executed by IPython's own
1722 processor.
1723
1724 -x: do not execute the edited code immediately upon exit. This is mainly
1725 useful if you are editing programs which need to be called with command
1726 line arguments, which you can then do using %run.
1727
1728 Arguments:
1729
1730 If arguments are given, the following possibilites exist:
1731
1732 - The arguments are numbers or pairs of dash-separated numbers (like 1
1733 4-8 9). These are interpreted as lines of previous input to be loaded
1734 into the editor. The syntax is the same of the %macro command.
1735
1736 - If the argument doesn't start with a number, it is evaluated as a
1737 variable and its contents loaded into the editor. You can thus edit any
1738 string which contains python code (including the result of previous edits).
1739
1740 - If the argument is the name of an object (other than a string),
1741 IPython will try to locate the file where it was defined and open the
1742 editor at the point where it is defined. You can use '%edit function' to
1743 load an editor exactly at the point where 'function' is defined, edit it
1744 and have the file be executed automatically.
1745
1746 If the object is a macro (see %macro for details), this opens up your
1747 specified editor with a temporary file containing the macro's data. Upon
1748 exit, the macro is reloaded with the contents of the file.
1749
1750 Note: opening at an exact line is only supported under Unix, and some
1751 editors (like kedit and gedit up to Gnome 2.8) do not understand the
1752 '+NUMBER' parameter necessary for this feature. Good editors like
1753 (X)Emacs, vi, jed, pico and joe all do.
1754
1755 If the argument is not found as a variable, IPython will look for a
1756 file with that name (adding .py if necessary) and load it into the
1757 editor. It will execute its contents with execfile() when you exit,
1758 loading any code in the file into your interactive namespace.
1759
1760 After executing your code, %edit will return as output the code you
1761 typed in the editor (except when it was an existing file). This way you
1762 can reload the code in further invocations of %edit as a variable, via
1763 _<NUMBER> or Out[<NUMBER>], where <NUMBER> is the prompt number of the
1764 output.
1765
1766 Note that %edit is also available through the alias %ed.
1767
1768 This is an example of creating a simple function inside the editor and
1769 then modifying it. First, start up the editor::
1770
1771 In [1]: ed
1772 Editing... done. Executing edited code...
1773 Out[1]: 'def foo():\n print "foo() was defined in an editing session"\n'
1774
1775 We can then call the function foo():
1776
1777 In [2]: foo()
1778 foo() was defined in an editing session
1779
1780 Now we edit foo. IPython automatically loads the editor with the
1781 (temporary) file where foo() was previously defined:
1782
1783 In [3]: ed foo
1784 Editing... done. Executing edited code...
1785
1786 And if we call foo() again we get the modified version:
1787
1788 In [4]: foo()
1789 foo() has now been changed!
1790
1791 Here is an example of how to edit a code snippet successive times. First
1792 we call the editor:
1793
1794 In [8]: ed
1795 Editing... done. Executing edited code...
1796 hello
1797 Out[8]: "print 'hello'\n"
1798
1799 Now we call it again with the previous output (stored in _):
1800
1801 In [9]: ed _
1802 Editing... done. Executing edited code...
1803 hello world
1804 Out[9]: "print 'hello world'\n"
1805
1806 Now we call it with the output #8 (stored in _8, also as Out[8]):
1807
1808 In [10]: ed _8
1809 Editing... done. Executing edited code...
1810 hello again
1811 Out[10]: "print 'hello again'\n"
1812
1813 Changing the default editor hook:
1814
1815 If you wish to write your own editor hook, you can put it in a
1816 configuration file which you load at startup time. The default hook is
1817 defined in the IPython.hooks module, and you can use that as a starting
1818 example for further modifications. That file also has general
1819 instructions on how to set a new hook for use once you've defined it.
1820
1821
1822 %env: List environment variables.
1823
1824
1825 %exit: Exit IPython, confirming if configured to do so.
1826
1827 You can configure whether IPython asks for confirmation upon exit by
1828 setting the confirm_exit flag in the ipythonrc file.
1829
1830
1831 %logoff: Temporarily stop logging.
1832
1833 You must have previously started logging.
1834
1835
1836 %logon: Restart logging.
1837
1838 This function is for restarting logging which you've temporarily stopped
1839 with %logoff. For starting logging for the first time, you must use the
1840 %logstart function, which allows you to specify an optional log filename.
1841
1842
1843 %logstart: Start logging anywhere in a session.
1844
1845 %logstart [-o|-r|-t] [log_name [log_mode]]
1846
1847 If no name is given, it defaults to a file named 'ipython_log.py' in
1848 your current directory, in 'rotate' mode (see below).
1849
1850 '%logstart name' saves to file 'name' in 'backup' mode. It saves your
1851 history up to that point and then continues logging.
1852
1853 %logstart takes a second optional parameter: logging mode. This can be
1854 one of (note that the modes are given unquoted):
1855 append: well, that says it.
1856 backup: rename (if exists) to name and start name.
1857 global: single logfile in your home dir, appended to.
1858 over : overwrite existing log.
1859 rotate: create rotating logs name.1 , name.2 , etc.
1860
1861 Options:
1862
1863 -o: log also IPython's output. In this mode, all commands which generate
1864 an Out[NN] prompt are recorded to the logfile, right after their
1865 corresponding input line. The output lines are always prepended with a
1866 '#[Out]# ' marker, so that the log remains valid Python code.
1867
1868 Since this marker is always the same, filtering only the output from a
1869 log is very easy, using for example a simple awk call:
1870
1871 awk -F'#
1872
1873 \begin{displaymath}Out\end{displaymath}
1874
1875 # ' 'if($2) print $2' ipython_log.py
1876
1877 -r: log 'raw' input. Normally, IPython's logs contain the processed
1878 input, so that user lines are logged in their final form, converted into
1879 valid Python. For example, %Exit is logged as '_ip.magic("Exit"). If the
1880 -r flag is given, all input is logged exactly as typed, with no
1881 transformations applied.
1882
1883 -t: put timestamps before each input line logged (these are put in
1884 comments).
1885
1886
1887 %logstate: Print the status of the logging system.
1888
1889
1890 %logstop: Fully stop logging and close log file.
1891
1892 In order to start logging again, a new %logstart call needs to be made,
1893 possibly (though not necessarily) with a new filename, mode and other
1894 options.
1895
1896
1897 %lsmagic: List currently available magic functions.
1898
1899
1900 %macro: Define a set of input lines as a macro for future re-execution.
1901
1902 Usage:
1903 %macro [options] name n1-n2 n3-n4 ... n5 .. n6 ...
1904
1905 Options:
1906
1907 -r: use 'raw' input. By default, the 'processed' history is used, so
1908 that magics are loaded in their transformed version to valid Python. If
1909 this option is given, the raw input as typed as the command line is used
1910 instead.
1911
1912 This will define a global variable called 'name' which is a string made
1913 of joining the slices and lines you specify (n1,n2,... numbers above)
1914 from your input history into a single string. This variable acts like an
1915 automatic function which re-executes those lines as if you had typed
1916 them. You just type 'name' at the prompt and the code executes.
1917
1918 The notation for indicating number ranges is: n1-n2 means 'use line
1919 numbers n1,...n2' (the endpoint is included). That is, '5-7' means using
1920 the lines numbered 5,6 and 7.
1921
1922 Note: as a 'hidden' feature, you can also use traditional python slice
1923 notation, where N:M means numbers N through M-1.
1924
1925 For example, if your history contains (%hist prints it):
1926
1927 44: x=1
1928 45: y=3
1929 46: z=x+y
1930 47: print x
1931 48: a=5
1932 49: print 'x',x,'y',y
1933
1934 you can create a macro with lines 44 through 47 (included) and line 49
1935 called my_macro with:
1936
1937 In [51]: %macro my_macro 44-47 49
1938
1939 Now, typing 'my_macro' (without quotes) will re-execute all this code in
1940 one pass.
1941
1942 You don't need to give the line-numbers in order, and any given line
1943 number can appear multiple times. You can assemble macros with any lines
1944 from your input history in any order.
1945
1946 The macro is a simple object which holds its value in an attribute, but
1947 IPython's display system checks for macros and executes them as code
1948 instead of printing them when you type their name.
1949
1950 You can view a macro's contents by explicitly printing it with:
1951
1952 'print macro_name'.
1953
1954 For one-off cases which DON'T contain magic function calls in them you
1955 can obtain similar results by explicitly executing slices from your
1956 input history with:
1957
1958 In [60]: exec In[44:48]+In[49]
1959
1960
1961 %magic: Print information about the magic function system.
1962
1963
1964 %page: Pretty print the object and display it through a pager.
1965
1966 %page [options] OBJECT
1967
1968 If no object is given, use _ (last output).
1969
1970 Options:
1971
1972 -r: page str(object), don't pretty-print it.
1973
1974
1975 %pdb: Control the automatic calling of the pdb interactive debugger.
1976
1977 Call as '%pdb on', '%pdb 1', '%pdb off' or '%pdb 0'. If called without
1978 argument it works as a toggle.
1979
1980 When an exception is triggered, IPython can optionally call the
1981 interactive pdb debugger after the traceback printout. %pdb toggles this
1982 feature on and off.
1983
1984 The initial state of this feature is set in your ipythonrc configuration
1985 file (the variable is called 'pdb').
1986
1987 If you want to just activate the debugger AFTER an exception has fired,
1988 without having to type '%pdb on' and rerunning your code, you can use
1989 the %debug magic.
1990
1991
1992 %pdef: Print the definition header for any callable object.
1993
1994 If the object is a class, print the constructor information.
1995
1996
1997 %pdoc: Print the docstring for an object.
1998
1999 If the given object is a class, it will print both the class and the
2000 constructor docstrings.
2001
2002
2003 %pfile: Print (or run through pager) the file where an object is defined.
2004
2005 The file opens at the line where the object definition begins. IPython
2006 will honor the environment variable PAGER if set, and otherwise will do
2007 its best to print the file in a convenient form.
2008
2009 If the given argument is not an object currently defined, IPython will
2010 try to interpret it as a filename (automatically adding a .py extension
2011 if needed). You can thus use %pfile as a syntax highlighting code viewer.
2012
2013
2014 %pinfo: Provide detailed information about an object.
2015
2016 '%pinfo object' is just a synonym for object? or ?object.
2017
2018
2019 %popd: Change to directory popped off the top of the stack.
2020
2021
2022 %profile: Print your currently active IPyhton profile.
2023
2024
2025 %prun: Run a statement through the python code profiler.
2026
2027 Usage:
2028 %prun [options] statement
2029
2030 The given statement (which doesn't require quote marks) is run via the
2031 python profiler in a manner similar to the profile.run() function.
2032 Namespaces are internally managed to work correctly; profile.run cannot
2033 be used in IPython because it makes certain assumptions about namespaces
2034 which do not hold under IPython.
2035
2036 Options:
2037
2038 -l <limit>: you can place restrictions on what or how much of the
2039 profile gets printed. The limit value can be:
2040
2041 * A string: only information for function names containing this string
2042 is printed.
2043
2044 * An integer: only these many lines are printed.
2045
2046 * A float (between 0 and 1): this fraction of the report is printed (for
2047 example, use a limit of 0.4 to see the topmost 40% only).
2048
2049 You can combine several limits with repeated use of the option. For
2050 example, '-l __init__ -l 5' will print only the topmost 5 lines of
2051 information about class constructors.
2052
2053 -r: return the pstats.Stats object generated by the profiling. This
2054 object has all the information about the profile in it, and you can
2055 later use it for further analysis or in other functions.
2056
2057 -s <key>: sort profile by given key. You can provide more than one key
2058 by using the option several times: '-s key1 -s key2 -s key3...'. The
2059 default sorting key is 'time'.
2060
2061 The following is copied verbatim from the profile documentation
2062 referenced below:
2063
2064 When more than one key is provided, additional keys are used as
2065 secondary criteria when the there is equality in all keys selected
2066 before them.
2067
2068 Abbreviations can be used for any key names, as long as the abbreviation
2069 is unambiguous. The following are the keys currently defined:
2070
2071 Valid Arg Meaning
2072 "calls" call count
2073 "cumulative" cumulative time
2074 "file" file name
2075 "module" file name
2076 "pcalls" primitive call count
2077 "line" line number
2078 "name" function name
2079 "nfl" name/file/line
2080 "stdname" standard name
2081 "time" internal time
2082
2083 Note that all sorts on statistics are in descending order (placing most
2084 time consuming items first), where as name, file, and line number
2085 searches are in ascending order (i.e., alphabetical). The subtle
2086 distinction between "nfl" and "stdname" is that the standard name is a
2087 sort of the name as printed, which means that the embedded line numbers
2088 get compared in an odd way. For example, lines 3, 20, and 40 would (if
2089 the file names were the same) appear in the string order "20" "3" and
2090 "40". In contrast, "nfl" does a numeric compare of the line numbers. In
2091 fact, sort_stats("nfl") is the same as sort_stats("name", "file", "line").
2092
2093 -T <filename>: save profile results as shown on screen to a text file.
2094 The profile is still shown on screen.
2095
2096 -D <filename>: save (via dump_stats) profile statistics to given
2097 filename. This data is in a format understod by the pstats module, and
2098 is generated by a call to the dump_stats() method of profile objects.
2099 The profile is still shown on screen.
2100
2101 If you want to run complete programs under the profiler's control, use
2102 '%run -p [prof_opts] filename.py [args to program]' where prof_opts
2103 contains profiler specific options as described here.
2104
2105 You can read the complete documentation for the profile module with:
2106 In [1]: import profile; profile.help()
2107
2108
2109 %psearch: Search for object in namespaces by wildcard.
2110
2111 %psearch [options] PATTERN [OBJECT TYPE]
2112
2113 Note: ? can be used as a synonym for %psearch, at the beginning or at
2114 the end: both a*? and ?a* are equivalent to '%psearch a*'. Still, the
2115 rest of the command line must be unchanged (options come first), so for
2116 example the following forms are equivalent
2117
2118 %psearch -i a* function -i a* function? ?-i a* function
2119
2120 Arguments:
2121
2122 PATTERN
2123
2124 where PATTERN is a string containing * as a wildcard similar to its use
2125 in a shell. The pattern is matched in all namespaces on the search path.
2126 By default objects starting with a single _ are not matched, many
2127 IPython generated objects have a single underscore. The default is case
2128 insensitive matching. Matching is also done on the attributes of objects
2129 and not only on the objects in a module.
2130
2131 [OBJECT TYPE]
2132
2133 Is the name of a python type from the types module. The name is given in
2134 lowercase without the ending type, ex. StringType is written string. By
2135 adding a type here only objects matching the given type are matched.
2136 Using all here makes the pattern match all types (this is the default).
2137
2138 Options:
2139
2140 -a: makes the pattern match even objects whose names start with a single
2141 underscore. These names are normally ommitted from the search.
2142
2143 -i/-c: make the pattern case insensitive/sensitive. If neither of these
2144 options is given, the default is read from your ipythonrc file. The
2145 option name which sets this value is 'wildcards_case_sensitive'. If this
2146 option is not specified in your ipythonrc file, IPython's internal
2147 default is to do a case sensitive search.
2148
2149 -e/-s NAMESPACE: exclude/search a given namespace. The pattern you
2150 specifiy can be searched in any of the following namespaces: 'builtin',
2151 'user', 'user_global','internal', 'alias', where 'builtin' and 'user'
2152 are the search defaults. Note that you should not use quotes when
2153 specifying namespaces.
2154
2155 'Builtin' contains the python module builtin, 'user' contains all user
2156 data, 'alias' only contain the shell aliases and no python objects,
2157 'internal' contains objects used by IPython. The 'user_global' namespace
2158 is only used by embedded IPython instances, and it contains module-level
2159 globals. You can add namespaces to the search with -s or exclude them
2160 with -e (these options can be given more than once).
2161
2162 Examples:
2163
2164 %psearch a* -> objects beginning with an a %psearch -e builtin a* ->
2165 objects NOT in the builtin space starting in a %psearch a* function ->
2166 all functions beginning with an a %psearch re.e* -> objects beginning
2167 with an e in module re %psearch r*.e* -> objects that start with e in
2168 modules starting in r %psearch r*.* string -> all strings in modules
2169 beginning with r
2170
2171 Case sensitve search:
2172
2173 %psearch -c a* list all object beginning with lower case a
2174
2175 Show objects beginning with a single _:
2176
2177 %psearch -a _* list objects beginning with a single underscore
2178
2179
2180 %psource: Print (or run through pager) the source code for an object.
2181
2182
2183 %pushd: Place the current dir on stack and change directory.
2184
2185 Usage:
2186 %pushd ['dirname']
2187
2188
2189 %pwd: Return the current working directory path.
2190
2191
2192 %pycat: Show a syntax-highlighted file through a pager.
2193
2194 This magic is similar to the cat utility, but it will assume the file to
2195 be Python source and will show it with syntax highlighting.
2196
2197
2198 %quickref: Show a quick reference sheet
2199
2200
2201 %quit: Exit IPython, confirming if configured to do so (like %exit)
2202
2203
2204 %r: Repeat previous input.
2205
2206 Note: Consider using the more powerfull %rep instead!
2207
2208 If given an argument, repeats the previous command which starts with the
2209 same string, otherwise it just repeats the previous input.
2210
2211 Shell escaped commands (with ! as first character) are not recognized by
2212 this system, only pure python code and magic commands.
2213
2214
2215 %rehashx: Update the alias table with all executable files in $PATH.
2216
2217 This version explicitly checks that every entry in $PATH is a file with
2218 execute access (os.X_OK), so it is much slower than %rehash.
2219
2220 Under Windows, it checks executability as a match agains a ``|``-separated
2221 string of extensions, stored in the IPython config variable
2222 win_exec_ext. This defaults to ``exe|com|bat``.
2223
2224 This function also resets the root module cache of module completer,
2225 used on slow filesystems.
2226
2227
2228 %reset: Resets the namespace by removing all names defined by the user.
2229
2230 Input/Output history are left around in case you need them.
2231
2232
2233 %run: Run the named file inside IPython as a program.
2234
2235 Usage:
2236 %run [-n -i -t [-N<N>] -d [-b<N>] -p [profile options]] file [args]
2237
2238 Parameters after the filename are passed as command-line arguments to
2239 the program (put in sys.argv). Then, control returns to IPython's prompt.
2240
2241 This is similar to running at a system prompt:
2242 $ python file args
2243 but with the advantage of giving you IPython's tracebacks, and of
2244 loading all variables into your interactive namespace for further use
2245 (unless -p is used, see below).
2246
2247 The file is executed in a namespace initially consisting only of
2248 __name__=='__main__' and sys.argv constructed as indicated. It thus sees
2249 its environment as if it were being run as a stand-alone program (except
2250 for sharing global objects such as previously imported modules). But
2251 after execution, the IPython interactive namespace gets updated with all
2252 variables defined in the program (except for __name__ and sys.argv).
2253 This allows for very convenient loading of code for interactive work,
2254 while giving each program a 'clean sheet' to run in.
2255
2256 Options:
2257
2258 -n: __name__ is NOT set to '__main__', but to the running file's name
2259 without extension (as python does under import). This allows running
2260 scripts and reloading the definitions in them without calling code
2261 protected by an ' if __name__ == "__main__" ' clause.
2262
2263 -i: run the file in IPython's namespace instead of an empty one. This is
2264 useful if you are experimenting with code written in a text editor which
2265 depends on variables defined interactively.
2266
2267 -e: ignore sys.exit() calls or SystemExit exceptions in the script being
2268 run. This is particularly useful if IPython is being used to run
2269 unittests, which always exit with a sys.exit() call. In such cases you
2270 are interested in the output of the test results, not in seeing a
2271 traceback of the unittest module.
2272
2273 -t: print timing information at the end of the run. IPython will give
2274 you an estimated CPU time consumption for your script, which under Unix
2275 uses the resource module to avoid the wraparound problems of
2276 time.clock(). Under Unix, an estimate of time spent on system tasks is
2277 also given (for Windows platforms this is reported as 0.0).
2278
2279 If -t is given, an additional -N<N> option can be given, where <N> must
2280 be an integer indicating how many times you want the script to run. The
2281 final timing report will include total and per run results.
2282
2283 For example (testing the script uniq_stable.py):
2284
2285 In [1]: run -t uniq_stable
2286
2287 IPython CPU timings (estimated):
2288 User : 0.19597 s.
2289 System: 0.0 s.
2290
2291 In [2]: run -t -N5 uniq_stable
2292
2293 IPython CPU timings (estimated):
2294 Total runs performed: 5
2295 Times : Total Per run
2296 User : 0.910862 s, 0.1821724 s.
2297 System: 0.0 s, 0.0 s.
2298
2299 -d: run your program under the control of pdb, the Python debugger. This
2300 allows you to execute your program step by step, watch variables, etc.
2301 Internally, what IPython does is similar to calling:
2302
2303 pdb.run('execfile("YOURFILENAME")')
2304
2305 with a breakpoint set on line 1 of your file. You can change the line
2306 number for this automatic breakpoint to be <N> by using the -bN option
2307 (where N must be an integer). For example:
2308
2309 %run -d -b40 myscript
2310
2311 will set the first breakpoint at line 40 in myscript.py. Note that the
2312 first breakpoint must be set on a line which actually does something
2313 (not a comment or docstring) for it to stop execution.
2314
2315 When the pdb debugger starts, you will see a (Pdb) prompt. You must
2316 first enter 'c' (without qoutes) to start execution up to the first
2317 breakpoint.
2318
2319 Entering 'help' gives information about the use of the debugger. You can
2320 easily see pdb's full documentation with "import pdb;pdb.help()" at a
2321 prompt.
2322
2323 -p: run program under the control of the Python profiler module (which
2324 prints a detailed report of execution times, function calls, etc).
2325
2326 You can pass other options after -p which affect the behavior of the
2327 profiler itself. See the docs for %prun for details.
2328
2329 In this mode, the program's variables do NOT propagate back to the
2330 IPython interactive namespace (because they remain in the namespace
2331 where the profiler executes them).
2332
2333 Internally this triggers a call to %prun, see its documentation for
2334 details on the options available specifically for profiling.
2335
2336 There is one special usage for which the text above doesn't apply: if
2337 the filename ends with .ipy, the file is run as ipython script, just as
2338 if the commands were written on IPython prompt.
2339
2340
2341 %runlog: Run files as logs.
2342
2343 Usage:
2344 %runlog file1 file2 ...
2345
2346 Run the named files (treating them as log files) in sequence inside the
2347 interpreter, and return to the prompt. This is much slower than %run
2348 because each line is executed in a try/except block, but it allows
2349 running files with syntax errors in them.
2350
2351 Normally IPython will guess when a file is one of its own logfiles, so
2352 you can typically use %run even for logs. This shorthand allows you to
2353 force any file to be treated as a log file.
2354
2355
2356 %save: Save a set of lines to a given filename.
2357
2358 Usage:
2359 %save [options] filename n1-n2 n3-n4 ... n5 .. n6 ...
2360
2361 Options:
2362
2363 -r: use 'raw' input. By default, the 'processed' history is used, so
2364 that magics are loaded in their transformed version to valid Python. If
2365 this option is given, the raw input as typed as the command line is used
2366 instead.
2367
2368 This function uses the same syntax as %macro for line extraction, but
2369 instead of creating a macro it saves the resulting string to the
2370 filename you specify.
2371
2372 It adds a '.py' extension to the file if you don't do so yourself, and
2373 it asks for confirmation before overwriting existing files.
2374
2375
2376 %sc: Shell capture - execute a shell command and capture its output.
2377
2378 DEPRECATED. Suboptimal, retained for backwards compatibility.
2379
2380 You should use the form 'var = !command' instead. Example:
2381
2382 "%sc -l myfiles = ls " should now be written as
2383
2384 "myfiles = !ls "
2385
2386 myfiles.s, myfiles.l and myfiles.n still apply as documented below.
2387
2388 - %sc [options] varname=command
2389
2390 IPython will run the given command using commands.getoutput(), and will
2391 then update the user's interactive namespace with a variable called
2392 varname, containing the value of the call. Your command can contain
2393 shell wildcards, pipes, etc.
2394
2395 The '=' sign in the syntax is mandatory, and the variable name you
2396 supply must follow Python's standard conventions for valid names.
2397
2398 (A special format without variable name exists for internal use)
2399
2400 Options:
2401
2402 -l: list output. Split the output on newlines into a list before
2403 assigning it to the given variable. By default the output is stored as a
2404 single string.
2405
2406 -v: verbose. Print the contents of the variable.
2407
2408 In most cases you should not need to split as a list, because the
2409 returned value is a special type of string which can automatically
2410 provide its contents either as a list (split on newlines) or as a
2411 space-separated string. These are convenient, respectively, either for
2412 sequential processing or to be passed to a shell command.
2413
2414 For example:
2415
2416 # Capture into variable a In [9]: sc a=ls *py
2417
2418 # a is a string with embedded newlines In [10]: a Out[10]: 'setup.py
2419 win32_manual_post_install.py'
2420
2421 # which can be seen as a list: In [11]: a.l Out[11]: ['setup.py',
2422 'win32_manual_post_install.py']
2423
2424 # or as a whitespace-separated string: In [12]: a.s Out[12]: 'setup.py
2425 win32_manual_post_install.py'
2426
2427 # a.s is useful to pass as a single command line: In [13]: !wc -l $a.s
2428 146 setup.py 130 win32_manual_post_install.py 276 total
2429
2430 # while the list form is useful to loop over: In [14]: for f in a.l:
2431 ....: !wc -l $f ....: 146 setup.py 130 win32_manual_post_install.py
2432
2433 Similiarly, the lists returned by the -l option are also special, in the
2434 sense that you can equally invoke the .s attribute on them to
2435 automatically get a whitespace-separated string from their contents:
2436
2437 In [1]: sc -l b=ls *py
2438
2439 In [2]: b Out[2]: ['setup.py', 'win32_manual_post_install.py']
2440
2441 In [3]: b.s Out[3]: 'setup.py win32_manual_post_install.py'
2442
2443 In summary, both the lists and strings used for ouptut capture have the
2444 following special attributes:
2445
2446 .l (or .list) : value as list. .n (or .nlstr): value as
2447 newline-separated string. .s (or .spstr): value as space-separated string.
2448
2449
2450 %sx: Shell execute - run a shell command and capture its output.
2451
2452 %sx command
2453
2454 IPython will run the given command using commands.getoutput(), and
2455 return the result formatted as a list (split on '\n'). Since the output
2456 is _returned_, it will be stored in ipython's regular output cache
2457 Out[N] and in the '_N' automatic variables.
2458
2459 Notes:
2460
2461 1) If an input line begins with '!!', then %sx is automatically invoked.
2462 That is, while: !ls causes ipython to simply issue system('ls'), typing
2463 !!ls is a shorthand equivalent to: %sx ls
2464
2465 2) %sx differs from %sc in that %sx automatically splits into a list,
2466 like '%sc -l'. The reason for this is to make it as easy as possible to
2467 process line-oriented shell output via further python commands. %sc is
2468 meant to provide much finer control, but requires more typing.
2469
2470 3) Just like %sc -l, this is a list with special attributes:
2471
2472 .l (or .list) : value as list. .n (or .nlstr): value as
2473 newline-separated string. .s (or .spstr): value as whitespace-separated
2474 string.
2475
2476 This is very useful when trying to use such lists as arguments to system
2477 commands.
2478
2479
2480 %system_verbose: Set verbose printing of system calls.
2481
2482 If called without an argument, act as a toggle
2483
2484
2485 %time: Time execution of a Python statement or expression.
2486
2487 The CPU and wall clock times are printed, and the value of the
2488 expression (if any) is returned. Note that under Win32, system time is
2489 always reported as 0, since it can not be measured.
2490
2491 This function provides very basic timing functionality. In Python 2.3,
2492 the timeit module offers more control and sophistication, so this could
2493 be rewritten to use it (patches welcome).
2494
2495 Some examples:
2496
2497 In [1]: time 2**128 CPU times: user 0.00 s, sys: 0.00 s, total: 0.00 s
2498 Wall time: 0.00 Out[1]: 340282366920938463463374607431768211456L
2499
2500 In [2]: n = 1000000
2501
2502 In [3]: time sum(range(n)) CPU times: user 1.20 s, sys: 0.05 s, total:
2503 1.25 s Wall time: 1.37 Out[3]: 499999500000L
2504
2505 In [4]: time print 'hello world' hello world CPU times: user 0.00 s,
2506 sys: 0.00 s, total: 0.00 s Wall time: 0.00
2507
2508 Note that the time needed by Python to compile the given expression will
2509 be reported if it is more than 0.1s. In this example, the actual
2510 exponentiation is done by Python at compilation time, so while the
2511 expression can take a noticeable amount of time to compute, that time is
2512 purely due to the compilation:
2513
2514 In [5]: time 3**9999; CPU times: user 0.00 s, sys: 0.00 s, total: 0.00 s
2515 Wall time: 0.00 s
2516
2517 In [6]: time 3**999999; CPU times: user 0.00 s, sys: 0.00 s, total: 0.00
2518 s Wall time: 0.00 s Compiler : 0.78 s
2519
2520
2521 %timeit: Time execution of a Python statement or expression
2522
2523 Usage:
2524 %timeit [-n<N> -r<R> [-t|-c]] statement
2525
2526 Time execution of a Python statement or expression using the timeit module.
2527
2528 Options: -n<N>: execute the given statement <N> times in a loop. If this
2529 value is not given, a fitting value is chosen.
2530
2531 -r<R>: repeat the loop iteration <R> times and take the best result.
2532 Default: 3
2533
2534 -t: use time.time to measure the time, which is the default on Unix.
2535 This function measures wall time.
2536
2537 -c: use time.clock to measure the time, which is the default on Windows
2538 and measures wall time. On Unix, resource.getrusage is used instead and
2539 returns the CPU user time.
2540
2541 -p<P>: use a precision of <P> digits to display the timing result.
2542 Default: 3
2543
2544 Examples:
2545 In [1]: %timeit pass 10000000 loops, best of 3: 53.3 ns per loop
2546
2547 In [2]: u = None
2548
2549 In [3]: %timeit u is None 10000000 loops, best of 3: 184 ns per loop
2550
2551 In [4]: %timeit -r 4 u == None 1000000 loops, best of 4: 242 ns per loop
2552
2553 In [5]: import time
2554
2555 In [6]: %timeit -n1 time.sleep(2) 1 loops, best of 3: 2 s per loop
2556
2557 The times reported by %timeit will be slightly higher than those
2558 reported by the timeit.py script when variables are accessed. This is
2559 due to the fact that %timeit executes the statement in the namespace of
2560 the shell, compared with timeit.py, which uses a single setup statement
2561 to import function or create variables. Generally, the bias does not
2562 matter as long as results from timeit.py are not mixed with those from
2563 %timeit.
2564
2565
2566 %unalias: Remove an alias
2567
2568
2569 %upgrade: Upgrade your IPython installation
2570
2571 This will copy the config files that don't yet exist in your ipython dir
2572 from the system config dir. Use this after upgrading IPython if you
2573 don't wish to delete your .ipython dir.
2574
2575 Call with -nolegacy to get rid of ipythonrc* files (recommended for new
2576 users)
2577
2578
2579 %who: Print all interactive variables, with some minimal formatting.
2580
2581 If any arguments are given, only variables whose type matches one of
2582 these are printed. For example:
2583
2584 %who function str
2585
2586 will only list functions and strings, excluding all other types of
2587 variables. To find the proper type names, simply use type(var) at a
2588 command line to see how python prints type names. For example:
2589
2590 In [1]: type('hello')
2591 Out[1]: <type 'str'>
2592
2593 indicates that the type name for strings is 'str'.
2594
2595 %who always excludes executed names loaded through your configuration
2596 file and things which are internal to IPython.
2597
2598 This is deliberate, as typically you may load many modules and the
2599 purpose of %who is to show you only what you've manually defined.
2600
2601
2602 %who_ls: Return a sorted list of all interactive variables.
2603
2604 If arguments are given, only variables of types matching these arguments
2605 are returned.
2606
2607
2608 %whos: Like %who, but gives some extra information about each variable.
2609
2610 The same type filtering of %who can be applied here.
2611
2612 For all variables, the type is printed. Additionally it prints:
2613
2614 - For ,[],(): their length.
2615
2616 - For numpy and Numeric arrays, a summary with shape, number of
2617 elements, typecode and size in memory.
2618
2619 - Everything else: a string representation, snipping their middle if too
2620 long.
2621
2622
2623 %xmode: Switch modes for the exception handlers.
2624
2625 Valid modes: Plain, Context and Verbose.
2626
2627 If called without arguments, acts as a toggle.
2628
2629
2630 Access to the standard Python help
2631 ----------------------------------
2614 2632
2615 2633 As of Python 2.1, a help system is available with access to object
2616 2634 docstrings and the Python manuals. Simply type 'help' (no quotes) to
2617 2635 access it. You can also type help(object) to obtain information about a
2618 2636 given object, and help('keyword') for information on a keyword. As noted
2619 2637 in sec. 3.1 <node3.html#sec:help-access>, you need to properly configure
2620 2638 your environment variable PYTHONDOCS for this feature to work correctly.
2621 2639
2622 2640
2623 2641
2624 Dynamic object information
2642 Dynamic object information
2643 --------------------------
2625 2644
2626 2645 Typing ?word or word? prints detailed information about an object. If
2627 2646 certain strings in the object are too long (docstrings, code, etc.) they
2628 2647 get snipped in the center for brevity. This system gives access variable
2629 2648 types and values, full source code for any object (if available),
2630 2649 function prototypes and other useful information.
2631 2650
2632 2651 Typing ??word or word?? gives access to the full information without
2633 2652 snipping long strings. Long strings are sent to the screen through the
2634 2653 less pager if longer than the screen and printed otherwise. On systems
2635 2654 lacking the less command, IPython uses a very basic internal pager.
2636 2655
2637 2656 The following magic functions are particularly useful for gathering
2638 2657 information about your working environment. You can get more details by
2639 2658 typing %magic or querying them individually (use %function_name? with or
2640 2659 without the %), this is just a summary:
2641 2660
2642 2661 * [%pdoc <object>:] Print (or run through a pager if too long) the
2643 2662 docstring for an object. If the given object is a class, it will
2644 2663 print both the class and the constructor docstrings.
2645 2664 * [%pdef <object>:] Print the definition header for any callable
2646 2665 object. If the object is a class, print the constructor information.
2647 2666 * [%psource <object>:] Print (or run through a pager if too long)
2648 2667 the source code for an object.
2649 2668 * [%pfile <object>:] Show the entire source file where an object was
2650 2669 defined via a pager, opening it at the line where the object
2651 2670 definition begins.
2652 2671 * [%who/%whos:] These functions give information about identifiers
2653 2672 you have defined interactively (not things you loaded or defined
2654 2673 in your configuration files). %who just prints a list of
2655 2674 identifiers and %whos prints a table with some basic details about
2656 2675 each identifier.
2657 2676
2658 2677 Note that the dynamic object information functions (?/??, %pdoc, %pfile,
2659 2678 %pdef, %psource) give you access to documentation even on things which
2660 2679 are not really defined as separate identifiers. Try for example typing
2661 2680 {}.get? or after doing import os, type os.path.abspath??.
2662 2681
2663 2682
2664 2683
2665 Readline-based features
2684 Readline-based features
2685 -----------------------
2666 2686
2667 2687 These features require the GNU readline library, so they won't work if
2668 2688 your Python installation lacks readline support. We will first describe
2669 2689 the default behavior IPython uses, and then how to change it to suit
2670 2690 your preferences.
2671 2691
2672 2692
2673 2693 Command line completion
2674 2694 -----------------------
2675 2695
2676 2696 At any time, hitting TAB will complete any available python commands or
2677 2697 variable names, and show you a list of the possible completions if
2678 2698 there's no unambiguous one. It will also complete filenames in the
2679 2699 current directory if no python names match what you've typed so far.
2680 2700
2681 2701
2682 2702 Search command history
2683 2703 ----------------------
2684 2704
2685 2705 IPython provides two ways for searching through previous input and thus
2686 2706 reduce the need for repetitive typing:
2687 2707
2688 2708 1. Start typing, and then use Ctrl-p (previous,up) and Ctrl-n
2689 2709 (next,down) to search through only the history items that match
2690 2710 what you've typed so far. If you use Ctrl-p/Ctrl-n at a blank
2691 2711 prompt, they just behave like normal arrow keys.
2692 2712 2. Hit Ctrl-r: opens a search prompt. Begin typing and the system
2693 2713 searches your history for lines that contain what you've typed so
2694 2714 far, completing as much as it can.
2695 2715
2696 2716
2697 2717 Persistent command history across sessions
2698 2718 ------------------------------------------
2699 2719
2700 2720 IPython will save your input history when it leaves and reload it next
2701 2721 time you restart it. By default, the history file is named
2702 2722 $IPYTHONDIR/history, but if you've loaded a named profile,
2703 2723 '-PROFILE_NAME' is appended to the name. This allows you to keep
2704 2724 separate histories related to various tasks: commands related to
2705 2725 numerical work will not be clobbered by a system shell history, for
2706 2726 example.
2707 2727
2708 2728
2709 2729 Autoindent
2710 2730 ----------
2711 2731
2712 2732 IPython can recognize lines ending in ':' and indent the next line,
2713 2733 while also un-indenting automatically after 'raise' or 'return'.
2714 2734
2715 2735 This feature uses the readline library, so it will honor your ~/.inputrc
2716 2736 configuration (or whatever file your INPUTRC variable points to). Adding
2717 2737 the following lines to your .inputrc file can make indenting/unindenting
2718 2738 more convenient (M-i indents, M-u unindents)::
2719 2739
2720 2740 $if Python
2721 2741 "\M-i": " "
2722 2742 "\M-u": "\d\d\d\d"
2723 2743 $endif
2724 2744
2725 2745 Note that there are 4 spaces between the quote marks after "M-i" above.
2726 2746
2727 2747 Warning: this feature is ON by default, but it can cause problems with
2728 2748 the pasting of multi-line indented code (the pasted code gets
2729 2749 re-indented on each line). A magic function %autoindent allows you to
2730 2750 toggle it on/off at runtime. You can also disable it permanently on in
2731 2751 your ipythonrc file (set autoindent 0).
2732 2752
2733 2753
2734 2754 Customizing readline behavior
2735 2755 -----------------------------
2736 2756
2737 2757 All these features are based on the GNU readline library, which has an
2738 2758 extremely customizable interface. Normally, readline is configured via a
2739 2759 file which defines the behavior of the library; the details of the
2740 2760 syntax for this can be found in the readline documentation available
2741 2761 with your system or on the Internet. IPython doesn't read this file (if
2742 2762 it exists) directly, but it does support passing to readline valid
2743 2763 options via a simple interface. In brief, you can customize readline by
2744 2764 setting the following options in your ipythonrc configuration file (note
2745 2765 that these options can not be specified at the command line):
2746 2766
2747 2767 * [readline_parse_and_bind:] this option can appear as many times as
2748 2768 you want, each time defining a string to be executed via a
2749 2769 readline.parse_and_bind() command. The syntax for valid commands
2750 2770 of this kind can be found by reading the documentation for the GNU
2751 2771 readline library, as these commands are of the kind which readline
2752 2772 accepts in its configuration file.
2753 2773 * [readline_remove_delims:] a string of characters to be removed
2754 2774 from the default word-delimiters list used by readline, so that
2755 2775 completions may be performed on strings which contain them. Do not
2756 2776 change the default value unless you know what you're doing.
2757 2777 * [readline_omit__names:] when tab-completion is enabled, hitting
2758 2778 <tab> after a '.' in a name will complete all attributes of an
2759 2779 object, including all the special methods whose names include
2760 2780 double underscores (like __getitem__ or __class__). If you'd
2761 2781 rather not see these names by default, you can set this option to
2762 2782 1. Note that even when this option is set, you can still see those
2763 2783 names by explicitly typing a _ after the period and hitting <tab>:
2764 2784 'name._<tab>' will always complete attribute names starting with '_'.
2765 2785 * [ ] This option is off by default so that new users see all
2766 2786 attributes of any objects they are dealing with.
2767 2787
2768 2788 You will find the default values along with a corresponding detailed
2769 2789 explanation in your ipythonrc file.
2770 2790
2771 2791
2772 2792 Session logging and restoring
2773 2793 -----------------------------
2774 2794
2775 2795 You can log all input from a session either by starting IPython with the
2776 2796 command line switches -log or -logfile (see sec. 5.2
2777 2797 <node5.html#sec:cmd-line-opts>)or by activating the logging at any
2778 2798 moment with the magic function %logstart.
2779 2799
2780 2800 Log files can later be reloaded with the -logplay option and IPython
2781 2801 will attempt to 'replay' the log by executing all the lines in it, thus
2782 2802 restoring the state of a previous session. This feature is not quite
2783 2803 perfect, but can still be useful in many cases.
2784 2804
2785 2805 The log files can also be used as a way to have a permanent record of
2786 2806 any code you wrote while experimenting. Log files are regular text files
2787 2807 which you can later open in your favorite text editor to extract code or
2788 2808 to 'clean them up' before using them to replay a session.
2789 2809
2790 2810 The %logstart function for activating logging in mid-session is used as
2791 2811 follows:
2792 2812
2793 2813 %logstart [log_name [log_mode]]
2794 2814
2795 2815 If no name is given, it defaults to a file named 'log' in your
2796 2816 IPYTHONDIR directory, in 'rotate' mode (see below).
2797 2817
2798 2818 '%logstart name' saves to file 'name' in 'backup' mode. It saves your
2799 2819 history up to that point and then continues logging.
2800 2820
2801 2821 %logstart takes a second optional parameter: logging mode. This can be
2802 2822 one of (note that the modes are given unquoted):
2803 2823
2804 2824 * [over:] overwrite existing log_name.
2805 2825 * [backup:] rename (if exists) to log_name~ and start log_name.
2806 2826 * [append:] well, that says it.
2807 2827 * [rotate:] create rotating logs log_name.1~, log_name.2~, etc.
2808 2828
2809 2829 The %logoff and %logon functions allow you to temporarily stop and
2810 2830 resume logging to a file which had previously been started with
2811 2831 %logstart. They will fail (with an explanation) if you try to use them
2812 2832 before logging has been started.
2813 2833
2814 2834
2815 2835
2816 2836 System shell access
2817 2837 -------------------
2818 2838
2819 2839 Any input line beginning with a ! character is passed verbatim (minus
2820 2840 the !, of course) to the underlying operating system. For example,
2821 2841 typing !ls will run 'ls' in the current directory.
2822 2842
2823
2824 2843 Manual capture of command output
2825 2844 --------------------------------
2826 2845
2827 2846 If the input line begins with two exclamation marks, !!, the command is
2828 2847 executed but its output is captured and returned as a python list, split
2829 2848 on newlines. Any output sent by the subprocess to standard error is
2830 2849 printed separately, so that the resulting list only captures standard
2831 2850 output. The !! syntax is a shorthand for the %sx magic command.
2832 2851
2833 2852 Finally, the %sc magic (short for 'shell capture') is similar to %sx,
2834 2853 but allowing more fine-grained control of the capture details, and
2835 storing the result directly into a named variable.
2836
2837 See Sec. 6.2 <#sec:magic> for details on the magics %sc and %sx, or use
2838 IPython's own help (sc? and sx?) for further details.
2854 storing the result directly into a named variable. The direct use of
2855 %sc is now deprecated, and you should ise the ``var = !cmd`` syntax
2856 instead.
2839 2857
2840 2858 IPython also allows you to expand the value of python variables when
2841 2859 making system calls. Any python variable or expression which you prepend
2842 2860 with $ will get expanded before the system call is made::
2843 2861
2844 2862 In [1]: pyvar='Hello world'
2845 2863 In [2]: !echo "A python variable: $pyvar"
2846 2864 A python variable: Hello world
2847 2865
2848 2866 If you want the shell to actually see a literal $, you need to type it
2849 2867 twice::
2850 2868
2851 2869 In [3]: !echo "A system variable: $$HOME"
2852 2870 A system variable: /home/fperez
2853 2871
2854 2872 You can pass arbitrary expressions, though you'll need to delimit them
2855 2873 with {} if there is ambiguity as to the extent of the expression::
2856 2874
2857 2875 In [5]: x=10
2858 2876 In [6]: y=20
2859 2877 In [13]: !echo $x+y
2860 2878 10+y
2861 2879 In [7]: !echo ${x+y}
2862 2880 30
2863 2881
2864 2882 Even object attributes can be expanded::
2865 2883
2866 2884 In [12]: !echo $sys.argv
2867 2885 [/home/fperez/usr/bin/ipython]
2868 2886
2869 2887
2870 2888 System command aliases
2871 2889 ----------------------
2872 2890
2873 2891 The %alias magic function and the alias option in the ipythonrc
2874 2892 configuration file allow you to define magic functions which are in fact
2875 2893 system shell commands. These aliases can have parameters.
2876 2894
2877 2895 '%alias alias_name cmd' defines 'alias_name' as an alias for 'cmd'
2878 2896
2879 2897 Then, typing '%alias_name params' will execute the system command 'cmd
2880 2898 params' (from your underlying operating system).
2881 2899
2882 2900 You can also define aliases with parameters using %s specifiers (one per
2883 2901 parameter). The following example defines the %parts function as an
2884 2902 alias to the command 'echo first %s second %s' where each %s will be
2885 2903 replaced by a positional parameter to the call to %parts::
2886 2904
2887 2905 In [1]: alias parts echo first %s second %s
2888 2906 In [2]: %parts A B
2889 2907 first A second B
2890 2908 In [3]: %parts A
2891 2909 Incorrect number of arguments: 2 expected.
2892 2910 parts is an alias to: 'echo first %s second %s'
2893 2911
2894 2912 If called with no parameters, %alias prints the table of currently
2895 2913 defined aliases.
2896 2914
2897 2915 The %rehash/rehashx magics allow you to load your entire $PATH as
2898 2916 ipython aliases. See their respective docstrings (or sec. 6.2
2899 2917 <#sec:magic> for further details).
2900 2918
2901 2919
2902 2920
2903 2921 Recursive reload
2904 2922 ----------------
2905 2923
2906 2924 The dreload function does a recursive reload of a module: changes made
2907 2925 to the module since you imported will actually be available without
2908 2926 having to exit.
2909 2927
2910 2928
2911 2929 Verbose and colored exception traceback printouts
2912 2930 -------------------------------------------------
2913 2931
2914 2932 IPython provides the option to see very detailed exception tracebacks,
2915 2933 which can be especially useful when debugging large programs. You can
2916 2934 run any Python file with the %run function to benefit from these
2917 2935 detailed tracebacks. Furthermore, both normal and verbose tracebacks can
2918 2936 be colored (if your terminal supports it) which makes them much easier
2919 2937 to parse visually.
2920 2938
2921 2939 See the magic xmode and colors functions for details (just type %magic).
2922 2940
2923 2941 These features are basically a terminal version of Ka-Ping Yee's cgitb
2924 2942 module, now part of the standard Python library.
2925 2943
2926 2944
2927 2945
2928 2946 Input caching system
2929 2947 --------------------
2930 2948
2931 2949 IPython offers numbered prompts (In/Out) with input and output caching.
2932 2950 All input is saved and can be retrieved as variables (besides the usual
2933 2951 arrow key recall).
2934 2952
2935 2953 The following GLOBAL variables always exist (so don't overwrite them!):
2936 2954 _i: stores previous input. _ii: next previous. _iii: next-next previous.
2937 2955 _ih : a list of all input _ih[n] is the input from line n and this list
2938 2956 is aliased to the global variable In. If you overwrite In with a
2939 2957 variable of your own, you can remake the assignment to the internal list
2940 2958 with a simple 'In=_ih'.
2941 2959
2942 2960 Additionally, global variables named _i<n> are dynamically created (<n>
2943 2961 being the prompt counter), such that
2944 2962 _i<n> == _ih[<n>] == In[<n>].
2945 2963
2946 2964 For example, what you typed at prompt 14 is available as _i14, _ih[14]
2947 2965 and In[14].
2948 2966
2949 2967 This allows you to easily cut and paste multi line interactive prompts
2950 2968 by printing them out: they print like a clean string, without prompt
2951 2969 characters. You can also manipulate them like regular variables (they
2952 2970 are strings), modify or exec them (typing 'exec _i9' will re-execute the
2953 2971 contents of input prompt 9, 'exec In[9:14]+In[18]' will re-execute lines
2954 2972 9 through 13 and line 18).
2955 2973
2956 2974 You can also re-execute multiple lines of input easily by using the
2957 2975 magic %macro function (which automates the process and allows
2958 2976 re-execution without having to type 'exec' every time). The macro system
2959 2977 also allows you to re-execute previous lines which include magic
2960 2978 function calls (which require special processing). Type %macro? or see
2961 2979 sec. 6.2 <#sec:magic> for more details on the macro system.
2962 2980
2963 2981 A history function %hist allows you to see any part of your input
2964 2982 history by printing a range of the _i variables.
2965 2983
2966 2984 Output caching system
2967 2985 ---------------------
2968 2986
2969 2987 For output that is returned from actions, a system similar to the input
2970 2988 cache exists but using _ instead of _i. Only actions that produce a
2971 2989 result (NOT assignments, for example) are cached. If you are familiar
2972 2990 with Mathematica, IPython's _ variables behave exactly like
2973 2991 Mathematica's % variables.
2974 2992
2975 2993 The following GLOBAL variables always exist (so don't overwrite them!):
2976 2994
2977 2995 * [_] (a single underscore) : stores previous output, like Python's
2978 2996 default interpreter.
2979 2997 * [__] (two underscores): next previous.
2980 2998 * [___] (three underscores): next-next previous.
2981 2999
2982 3000 Additionally, global variables named _<n> are dynamically created (<n>
2983 3001 being the prompt counter), such that the result of output <n> is always
2984 3002 available as _<n> (don't use the angle brackets, just the number, e.g.
2985 3003 _21).
2986 3004
2987 3005 These global variables are all stored in a global dictionary (not a
2988 3006 list, since it only has entries for lines which returned a result)
2989 3007 available under the names _oh and Out (similar to _ih and In). So the
2990 3008 output from line 12 can be obtained as _12, Out[12] or _oh[12]. If you
2991 3009 accidentally overwrite the Out variable you can recover it by typing
2992 3010 'Out=_oh' at the prompt.
2993 3011
2994 3012 This system obviously can potentially put heavy memory demands on your
2995 3013 system, since it prevents Python's garbage collector from removing any
2996 3014 previously computed results. You can control how many results are kept
2997 3015 in memory with the option (at the command line or in your ipythonrc
2998 3016 file) cache_size. If you set it to 0, the whole system is completely
2999 3017 disabled and the prompts revert to the classic '>>>' of normal Python.
3000 3018
3001 3019
3002 3020 Directory history
3003 3021 -----------------
3004 3022
3005 3023 Your history of visited directories is kept in the global list _dh, and
3006 3024 the magic %cd command can be used to go to any entry in that list. The
3007 %dhist command allows you to view this history.
3025 %dhist command allows you to view this history. do ``cd -<TAB`` to
3026 conventiently view the directory history.
3008 3027
3009 3028
3010 3029 Automatic parentheses and quotes
3011 3030 --------------------------------
3012 3031
3013 3032 These features were adapted from Nathan Gray's LazyPython. They are
3014 3033 meant to allow less typing for common situations.
3015 3034
3016 3035
3017 3036 Automatic parentheses
3018 3037 ---------------------
3019 3038
3020 3039 Callable objects (i.e. functions, methods, etc) can be invoked like this
3021 3040 (notice the commas between the arguments)::
3022 3041
3023 3042 >>> callable_ob arg1, arg2, arg3
3024 3043
3025 3044 and the input will be translated to this::
3026 3045
3027 3046 -> callable_ob(arg1, arg2, arg3)
3028 3047
3029 3048 You can force automatic parentheses by using '/' as the first character
3030 3049 of a line. For example::
3031 3050
3032 3051 >>> /globals # becomes 'globals()'
3033 3052
3034 3053 Note that the '/' MUST be the first character on the line! This won't work::
3035 3054
3036 3055 >>> print /globals # syntax error
3037 3056
3038 3057 In most cases the automatic algorithm should work, so you should rarely
3039 3058 need to explicitly invoke /. One notable exception is if you are trying
3040 3059 to call a function with a list of tuples as arguments (the parenthesis
3041 3060 will confuse IPython)::
3042 3061
3043 3062 In [1]: zip (1,2,3),(4,5,6) # won't work
3044 3063
3045 3064 but this will work::
3046 3065
3047 3066 In [2]: /zip (1,2,3),(4,5,6)
3048 3067 ---> zip ((1,2,3),(4,5,6))
3049 3068 Out[2]= [(1, 4), (2, 5), (3, 6)]
3050 3069
3051 3070 IPython tells you that it has altered your command line by displaying
3052 3071 the new command line preceded by ->. e.g.::
3053 3072
3054 3073 In [18]: callable list
3055 3074 ----> callable (list)
3056 3075
3057 3076
3058 3077 Automatic quoting
3059 3078 -----------------
3060 3079
3061 3080 You can force automatic quoting of a function's arguments by using ','
3062 3081 or ';' as the first character of a line. For example::
3063 3082
3064 3083 >>> ,my_function /home/me # becomes my_function("/home/me")
3065 3084
3066 3085 If you use ';' instead, the whole argument is quoted as a single string
3067 3086 (while ',' splits on whitespace)::
3068 3087
3069 3088 >>> ,my_function a b c # becomes my_function("a","b","c")
3070 3089
3071 3090 >>> ;my_function a b c # becomes my_function("a b c")
3072 3091
3073 3092 Note that the ',' or ';' MUST be the first character on the line! This
3074 3093 won't work::
3075 3094
3076 3095 >>> x = ,my_function /home/me # syntax error
3077 3096
3078 3097 Customization
3079 3098 =============
3080 3099
3100 There are 2 ways to configure IPython - the old way of using ipythonrc
3101 files (an INI-file like format), and the new way that involves editing
3102 your ipy_user_conf.py. Both configuration systems work at the same
3103 time, so you can set your options in both, but if you are hesitating
3104 about which alternative to choose, we recommend the ipy_user_conf.py
3105 approach, as it will give you more power and control in the long
3106 run. However, there are few options such as pylab_import_all that can
3107 only be specified in ipythonrc file or command line - the reason for
3108 this is that they are needed before IPython has been started up, and
3109 the IPApi object used in ipy_user_conf.py is not yet available at that
3110 time. A hybrid approach of specifying a few options in ipythonrc and
3111 doing the more advanced configuration in ipy_user_conf.py is also
3112 possible.
3113
3114 The ipythonrc approach
3115 ----------------------
3116
3081 3117 As we've already mentioned, IPython reads a configuration file which can
3082 3118 be specified at the command line (-rcfile) or which by default is
3083 3119 assumed to be called ipythonrc. Such a file is looked for in the current
3084 3120 directory where IPython is started and then in your IPYTHONDIR, which
3085 3121 allows you to have local configuration files for specific projects. In
3086 3122 this section we will call these types of configuration files simply
3087 3123 rcfiles (short for resource configuration file).
3088 3124
3089 3125 The syntax of an rcfile is one of key-value pairs separated by
3090 3126 whitespace, one per line. Lines beginning with a # are ignored as
3091 3127 comments, but comments can not be put on lines with data (the parser is
3092 3128 fairly primitive). Note that these are not python files, and this is
3093 3129 deliberate, because it allows us to do some things which would be quite
3094 3130 tricky to implement if they were normal python files.
3095 3131
3096 3132 First, an rcfile can contain permanent default values for almost all
3097 3133 command line options (except things like -help or -Version). Sec 5.2
3098 3134 <node5.html#sec:cmd-line-opts> contains a description of all
3099 3135 command-line options. However, values you explicitly specify at the
3100 3136 command line override the values defined in the rcfile.
3101 3137
3102 3138 Besides command line option values, the rcfile can specify values for
3103 3139 certain extra special options which are not available at the command
3104 3140 line. These options are briefly described below.
3105 3141
3106 3142 Each of these options may appear as many times as you need it in the file.
3107 3143
3108 3144 * [include <file1> <file2> ...:] you can name other rcfiles you want
3109 3145 to recursively load up to 15 levels (don't use the <> brackets in
3110 3146 your names!). This feature allows you to define a 'base' rcfile
3111 3147 with general options and special-purpose files which can be loaded
3112 3148 only when needed with particular configuration options. To make
3113 3149 this more convenient, IPython accepts the -profile <name> option
3114 3150 (abbreviates to -p <name>) which tells it to look for an rcfile
3115 3151 named ipythonrc-<name>.
3116 3152 * [import_mod <mod1> <mod2> ...:] import modules with 'import
3117 3153 <mod1>,<mod2>,...'
3118 3154 * [import_some <mod> <f1> <f2> ...:] import functions with 'from
3119 3155 <mod> import <f1>,<f2>,...'
3120 3156 * [import_all <mod1> <mod2> ...:] for each module listed import
3121 functions with 'from <mod> import *'
3157 functions with ``from <mod> import *``.
3122 3158 * [execute <python code>:] give any single-line python code to be
3123 3159 executed.
3124 3160 * [execfile <filename>:] execute the python file given with an
3125 3161 'execfile(filename)' command. Username expansion is performed on
3126 3162 the given names. So if you need any amount of extra fancy
3127 3163 customization that won't fit in any of the above 'canned' options,
3128 3164 you can just put it in a separate python file and execute it.
3129 3165 * [alias <alias_def>:] this is equivalent to calling
3130 3166 '%alias <alias_def>' at the IPython command line. This way, from
3131 3167 within IPython you can do common system tasks without having to
3132 3168 exit it or use the ! escape. IPython isn't meant to be a shell
3133 3169 replacement, but it is often very useful to be able to do things
3134 3170 with files while testing code. This gives you the flexibility to
3135 3171 have within IPython any aliases you may be used to under your
3136 3172 normal system shell.
3137 3173
3138 3174
3139
3140 3175 Sample ipythonrc file
3141 3176 ---------------------
3142 3177
3143 3178 The default rcfile, called ipythonrc and supplied in your IPYTHONDIR
3144 3179 directory contains lots of comments on all of these options. We
3145 3180 reproduce it here for reference::
3146 3181
3147 3182
3148 3183 # -*- Mode: Shell-Script -*- Not really, but shows comments correctly
3149 3184 # $Id: ipythonrc 2156 2007-03-19 02:32:19Z fperez $
3150 3185
3151 3186 #***************************************************************************
3152 3187 #
3153 3188 # Configuration file for IPython -- ipythonrc format
3154 3189 #
3155 3190 # ===========================================================
3156 3191 # Deprecation note: you should look into modifying ipy_user_conf.py (located
3157 3192 # in ~/.ipython or ~/_ipython, depending on your platform) instead, it's a
3158 3193 # more flexible and robust (and better supported!) configuration
3159 3194 # method.
3160 3195 # ===========================================================
3161 3196 #
3162 3197 # The format of this file is simply one of 'key value' lines.
3163 3198 # Lines containing only whitespace at the beginning and then a # are ignored
3164 3199 # as comments. But comments can NOT be put on lines with data.
3165 3200
3166 3201 # The meaning and use of each key are explained below.
3167 3202
3168 3203 #---------------------------------------------------------------------------
3169 3204 # Section: included files
3170 3205
3171 3206 # Put one or more *config* files (with the syntax of this file) you want to
3172 3207 # include. For keys with a unique value the outermost file has precedence. For
3173 3208 # keys with multiple values, they all get assembled into a list which then
3174 3209 # gets loaded by IPython.
3175 3210
3176 3211 # In this file, all lists of things should simply be space-separated.
3177 3212
3178 3213 # This allows you to build hierarchies of files which recursively load
3179 3214 # lower-level services. If this is your main ~/.ipython/ipythonrc file, you
3180 3215 # should only keep here basic things you always want available. Then you can
3181 3216 # include it in every other special-purpose config file you create.
3182 3217 include
3183 3218
3184 3219 #---------------------------------------------------------------------------
3185 3220 # Section: startup setup
3186 3221
3187 3222 # These are mostly things which parallel a command line option of the same
3188 3223 # name.
3189 3224
3190 3225 # Keys in this section should only appear once. If any key from this section
3191 3226 # is encountered more than once, the last value remains, all earlier ones get
3192 3227 # discarded.
3193 3228
3194 3229
3195 3230 # Automatic calling of callable objects. If set to 1 or 2, callable objects
3196 3231 # are automatically called when invoked at the command line, even if you don't
3197 3232 # type parentheses. IPython adds the parentheses for you. For example:
3198 3233
3199 3234 #In [1]: str 45
3200 3235 #------> str(45)
3201 3236 #Out[1]: '45'
3202 3237
3203 3238 # IPython reprints your line with '---->' indicating that it added
3204 3239 # parentheses. While this option is very convenient for interactive use, it
3205 3240 # may occasionally cause problems with objects which have side-effects if
3206 3241 # called unexpectedly.
3207 3242
3208 3243 # The valid values for autocall are:
3209 3244
3210 3245 # autocall 0 -> disabled (you can toggle it at runtime with the %autocall magic)
3211 3246
3212 3247 # autocall 1 -> active, but do not apply if there are no arguments on the line.
3213 3248
3214 3249 # In this mode, you get:
3215 3250
3216 3251 #In [1]: callable
3217 3252 #Out[1]: <built-in function callable>
3218 3253
3219 3254 #In [2]: callable 'hello'
3220 3255 #------> callable('hello')
3221 3256 #Out[2]: False
3222 3257
3223 3258 # 2 -> Active always. Even if no arguments are present, the callable object
3224 3259 # is called:
3225 3260
3226 3261 #In [4]: callable
3227 3262 #------> callable()
3228 3263
3229 3264 # Note that even with autocall off, you can still use '/' at the start of a
3230 3265 # line to treat the first argument on the command line as a function and add
3231 3266 # parentheses to it:
3232 3267
3233 3268 #In [8]: /str 43
3234 3269 #------> str(43)
3235 3270 #Out[8]: '43'
3236 3271
3237 3272 autocall 1
3238 3273
3239 3274 # Auto-edit syntax errors. When you use the %edit magic in ipython to edit
3240 3275 # source code (see the 'editor' variable below), it is possible that you save
3241 3276 # a file with syntax errors in it. If this variable is true, IPython will ask
3242 3277 # you whether to re-open the editor immediately to correct such an error.
3243 3278
3244 3279 autoedit_syntax 0
3245 3280
3246 3281 # Auto-indent. IPython can recognize lines ending in ':' and indent the next
3247 3282 # line, while also un-indenting automatically after 'raise' or 'return'.
3248 3283
3249 3284 # This feature uses the readline library, so it will honor your ~/.inputrc
3250 3285 # configuration (or whatever file your INPUTRC variable points to). Adding
3251 3286 # the following lines to your .inputrc file can make indent/unindenting more
3252 3287 # convenient (M-i indents, M-u unindents):
3253 3288
3254 3289 # $if Python
3255 3290 # "\M-i": " "
3256 3291 # "\M-u": "\d\d\d\d"
3257 3292 # $endif
3258 3293
3259 3294 # The feature is potentially a bit dangerous, because it can cause problems
3260 3295 # with pasting of indented code (the pasted code gets re-indented on each
3261 3296 # line). But it's a huge time-saver when working interactively. The magic
3262 3297 # function %autoindent allows you to toggle it on/off at runtime.
3263 3298
3264 3299 autoindent 1
3265 3300
3266 3301 # Auto-magic. This gives you access to all the magic functions without having
3267 3302 # to prepend them with an % sign. If you define a variable with the same name
3268 3303 # as a magic function (say who=1), you will need to access the magic function
3269 3304 # with % (%who in this example). However, if later you delete your variable
3270 3305 # (del who), you'll recover the automagic calling form.
3271 3306
3272 3307 # Considering that many magic functions provide a lot of shell-like
3273 3308 # functionality, automagic gives you something close to a full Python+system
3274 3309 # shell environment (and you can extend it further if you want).
3275 3310
3276 3311 automagic 1
3277 3312
3278 3313 # Size of the output cache. After this many entries are stored, the cache will
3279 3314 # get flushed. Depending on the size of your intermediate calculations, you
3280 3315 # may have memory problems if you make it too big, since keeping things in the
3281 3316 # cache prevents Python from reclaiming the memory for old results. Experiment
3282 3317 # with a value that works well for you.
3283 3318
3284 3319 # If you choose cache_size 0 IPython will revert to python's regular >>>
3285 3320 # unnumbered prompt. You will still have _, __ and ___ for your last three
3286 3321 # results, but that will be it. No dynamic _1, _2, etc. will be created. If
3287 3322 # you are running on a slow machine or with very limited memory, this may
3288 3323 # help.
3289 3324
3290 3325 cache_size 1000
3291 3326
3292 3327 # Classic mode: Setting 'classic 1' you lose many of IPython niceties,
3293 3328 # but that's your choice! Classic 1 -> same as IPython -classic.
3294 3329 # Note that this is _not_ the normal python interpreter, it's simply
3295 3330 # IPython emulating most of the classic interpreter's behavior.
3296 3331 classic 0
3297 3332
3298 3333 # colors - Coloring option for prompts and traceback printouts.
3299 3334
3300 3335 # Currently available schemes: NoColor, Linux, LightBG.
3301 3336
3302 3337 # This option allows coloring the prompts and traceback printouts. This
3303 3338 # requires a terminal which can properly handle color escape sequences. If you
3304 3339 # are having problems with this, use the NoColor scheme (uses no color escapes
3305 3340 # at all).
3306 3341
3307 3342 # The Linux option works well in linux console type environments: dark
3308 3343 # background with light fonts.
3309 3344
3310 3345 # LightBG is similar to Linux but swaps dark/light colors to be more readable
3311 3346 # in light background terminals.
3312 3347
3313 3348 # keep uncommented only the one you want:
3314 3349 colors Linux
3315 3350 #colors LightBG
3316 3351 #colors NoColor
3317 3352
3318 3353 ########################
3319 3354 # Note to Windows users
3320 3355 #
3321 3356 # Color and readline support is avaialble to Windows users via Gary Bishop's
3322 3357 # readline library. You can find Gary's tools at
3323 3358 # http://sourceforge.net/projects/uncpythontools.
3324 3359 # Note that his readline module requires in turn the ctypes library, available
3325 3360 # at http://starship.python.net/crew/theller/ctypes.
3326 3361 ########################
3327 3362
3328 3363 # color_info: IPython can display information about objects via a set of
3329 3364 # functions, and optionally can use colors for this, syntax highlighting
3330 3365 # source code and various other elements. This information is passed through a
3331 3366 # pager (it defaults to 'less' if $PAGER is not set).
3332 3367
3333 3368 # If your pager has problems, try to setting it to properly handle escapes
3334 3369 # (see the less manpage for detail), or disable this option. The magic
3335 3370 # function %color_info allows you to toggle this interactively for testing.
3336 3371
3337 3372 color_info 1
3338 3373
3339 3374 # confirm_exit: set to 1 if you want IPython to confirm when you try to exit
3340 3375 # with an EOF (Control-d in Unix, Control-Z/Enter in Windows). Note that using
3341 3376 # the magic functions %Exit or %Quit you can force a direct exit, bypassing
3342 3377 # any confirmation.
3343 3378
3344 3379 confirm_exit 1
3345 3380
3346 3381 # Use deep_reload() as a substitute for reload() by default. deep_reload() is
3347 3382 # still available as dreload() and appears as a builtin.
3348 3383
3349 3384 deep_reload 0
3350 3385
3351 3386 # Which editor to use with the %edit command. If you leave this at 0, IPython
3352 3387 # will honor your EDITOR environment variable. Since this editor is invoked on
3353 3388 # the fly by ipython and is meant for editing small code snippets, you may
3354 3389 # want to use a small, lightweight editor here.
3355 3390
3356 3391 # For Emacs users, setting up your Emacs server properly as described in the
3357 3392 # manual is a good idea. An alternative is to use jed, a very light editor
3358 3393 # with much of the feel of Emacs (though not as powerful for heavy-duty work).
3359 3394
3360 3395 editor 0
3361 3396
3362 3397 # log 1 -> same as ipython -log. This automatically logs to ./ipython.log
3363 3398 log 0
3364 3399
3365 3400 # Same as ipython -Logfile YourLogfileName.
3366 3401 # Don't use with log 1 (use one or the other)
3367 3402 logfile ''
3368 3403
3369 3404 # banner 0 -> same as ipython -nobanner
3370 3405 banner 1
3371 3406
3372 3407 # messages 0 -> same as ipython -nomessages
3373 3408 messages 1
3374 3409
3375 3410 # Automatically call the pdb debugger after every uncaught exception. If you
3376 3411 # are used to debugging using pdb, this puts you automatically inside of it
3377 3412 # after any call (either in IPython or in code called by it) which triggers an
3378 3413 # exception which goes uncaught.
3379 3414 pdb 0
3380 3415
3381 3416 # Enable the pprint module for printing. pprint tends to give a more readable
3382 3417 # display (than print) for complex nested data structures.
3383 3418 pprint 1
3384 3419
3385 3420 # Prompt strings
3386 3421
3387 3422 # Most bash-like escapes can be used to customize IPython's prompts, as well as
3388 3423 # a few additional ones which are IPython-specific. All valid prompt escapes
3389 3424 # are described in detail in the Customization section of the IPython HTML/PDF
3390 3425 # manual.
3391 3426
3392 3427 # Use \# to represent the current prompt number, and quote them to protect
3393 3428 # spaces.
3394 3429 prompt_in1 'In [\#]: '
3395 3430
3396 3431 # \D is replaced by as many dots as there are digits in the
3397 3432 # current value of \#.
3398 3433 prompt_in2 ' .\D.: '
3399 3434
3400 3435 prompt_out 'Out[\#]: '
3401 3436
3402 3437 # Select whether to left-pad the output prompts to match the length of the
3403 3438 # input ones. This allows you for example to use a simple '>' as an output
3404 3439 # prompt, and yet have the output line up with the input. If set to false,
3405 3440 # the output prompts will be unpadded (flush left).
3406 3441 prompts_pad_left 1
3407 3442
3408 3443 # Pylab support: when ipython is started with the -pylab switch, by default it
3409 3444 # executes 'from matplotlib.pylab import *'. Set this variable to false if you
3410 3445 # want to disable this behavior.
3411 3446
3412 3447 # For details on pylab, see the matplotlib website:
3413 3448 # http://matplotlib.sf.net
3414 3449 pylab_import_all 1
3415 3450
3416 3451
3417 3452 # quick 1 -> same as ipython -quick
3418 3453 quick 0
3419 3454
3420 3455 # Use the readline library (1) or not (0). Most users will want this on, but
3421 3456 # if you experience strange problems with line management (mainly when using
3422 3457 # IPython inside Emacs buffers) you may try disabling it. Not having it on
3423 3458 # prevents you from getting command history with the arrow keys, searching and
3424 3459 # name completion using TAB.
3425 3460
3426 3461 readline 1
3427 3462
3428 3463 # Screen Length: number of lines of your screen. This is used to control
3429 3464 # printing of very long strings. Strings longer than this number of lines will
3430 3465 # be paged with the less command instead of directly printed.
3431 3466
3432 3467 # The default value for this is 0, which means IPython will auto-detect your
3433 3468 # screen size every time it needs to print. If for some reason this isn't
3434 3469 # working well (it needs curses support), specify it yourself. Otherwise don't
3435 3470 # change the default.
3436 3471
3437 3472 screen_length 0
3438 3473
3439 3474 # Prompt separators for input and output.
3440 3475 # Use \n for newline explicitly, without quotes.
3441 3476 # Use 0 (like at the cmd line) to turn off a given separator.
3442 3477
3443 3478 # The structure of prompt printing is:
3444 3479 # (SeparateIn)Input....
3445 3480 # (SeparateOut)Output...
3446 3481 # (SeparateOut2), # that is, no newline is printed after Out2
3447 3482 # By choosing these you can organize your output any way you want.
3448 3483
3449 3484 separate_in \n
3450 3485 separate_out 0
3451 3486 separate_out2 0
3452 3487
3453 3488 # 'nosep 1' is a shorthand for '-SeparateIn 0 -SeparateOut 0 -SeparateOut2 0'.
3454 3489 # Simply removes all input/output separators, overriding the choices above.
3455 3490 nosep 0
3456 3491
3457 3492 # Wildcard searches - IPython has a system for searching names using
3458 3493 # shell-like wildcards; type %psearch? for details. This variables sets
3459 3494 # whether by default such searches should be case sensitive or not. You can
3460 3495 # always override the default at the system command line or the IPython
3461 3496 # prompt.
3462 3497
3463 3498 wildcards_case_sensitive 1
3464 3499
3465 3500 # Object information: at what level of detail to display the string form of an
3466 3501 # object. If set to 0, ipython will compute the string form of any object X,
3467 3502 # by calling str(X), when X? is typed. If set to 1, str(X) will only be
3468 3503 # computed when X?? is given, and if set to 2 or higher, it will never be
3469 3504 # computed (there is no X??? level of detail). This is mostly of use to
3470 3505 # people who frequently manipulate objects whose string representation is
3471 3506 # extremely expensive to compute.
3472 3507
3473 3508 object_info_string_level 0
3474 3509
3475 3510 # xmode - Exception reporting mode.
3476 3511
3477 3512 # Valid modes: Plain, Context and Verbose.
3478 3513
3479 3514 # Plain: similar to python's normal traceback printing.
3480 3515
3481 3516 # Context: prints 5 lines of context source code around each line in the
3482 3517 # traceback.
3483 3518
3484 3519 # Verbose: similar to Context, but additionally prints the variables currently
3485 3520 # visible where the exception happened (shortening their strings if too
3486 3521 # long). This can potentially be very slow, if you happen to have a huge data
3487 3522 # structure whose string representation is complex to compute. Your computer
3488 3523 # may appear to freeze for a while with cpu usage at 100%. If this occurs, you
3489 3524 # can cancel the traceback with Ctrl-C (maybe hitting it more than once).
3490 3525
3491 3526 #xmode Plain
3492 3527 xmode Context
3493 3528 #xmode Verbose
3494 3529
3495 3530 # multi_line_specials: if true, allow magics, aliases and shell escapes (via
3496 3531 # !cmd) to be used in multi-line input (like for loops). For example, if you
3497 3532 # have this active, the following is valid in IPython:
3498 3533 #
3499 3534 #In [17]: for i in range(3):
3500 3535 # ....: mkdir $i
3501 3536 # ....: !touch $i/hello
3502 3537 # ....: ls -l $i
3503 3538
3504 3539 multi_line_specials 1
3505 3540
3506 3541
3507 3542 # System calls: When IPython makes system calls (e.g. via special syntax like
3508 3543 # !cmd or !!cmd, or magics like %sc or %sx), it can print the command it is
3509 3544 # executing to standard output, prefixed by a header string.
3510 3545
3511 3546 system_header "IPython system call: "
3512 3547
3513 3548 system_verbose 1
3514 3549
3515 3550 # wxversion: request a specific wxPython version (used for -wthread)
3516 3551
3517 3552 # Set this to the value of wxPython you want to use, but note that this
3518 3553 # feature requires you to have the wxversion Python module to work. If you
3519 3554 # don't have the wxversion module (try 'import wxversion' at the prompt to
3520 3555 # check) or simply want to leave the system to pick up the default, leave this
3521 3556 # variable at 0.
3522 3557
3523 3558 wxversion 0
3524 3559
3525 3560 #---------------------------------------------------------------------------
3526 3561 # Section: Readline configuration (readline is not available for MS-Windows)
3527 3562
3528 3563 # This is done via the following options:
3529 3564
3530 3565 # (i) readline_parse_and_bind: this option can appear as many times as you
3531 3566 # want, each time defining a string to be executed via a
3532 3567 # readline.parse_and_bind() command. The syntax for valid commands of this
3533 3568 # kind can be found by reading the documentation for the GNU readline library,
3534 3569 # as these commands are of the kind which readline accepts in its
3535 3570 # configuration file.
3536 3571
3537 3572 # The TAB key can be used to complete names at the command line in one of two
3538 3573 # ways: 'complete' and 'menu-complete'. The difference is that 'complete' only
3539 3574 # completes as much as possible while 'menu-complete' cycles through all
3540 3575 # possible completions. Leave the one you prefer uncommented.
3541 3576
3542 3577 readline_parse_and_bind tab: complete
3543 3578 #readline_parse_and_bind tab: menu-complete
3544 3579
3545 3580 # This binds Control-l to printing the list of all possible completions when
3546 3581 # there is more than one (what 'complete' does when hitting TAB twice, or at
3547 3582 # the first TAB if show-all-if-ambiguous is on)
3548 3583 readline_parse_and_bind "\C-l": possible-completions
3549 3584
3550 3585 # This forces readline to automatically print the above list when tab
3551 3586 # completion is set to 'complete'. You can still get this list manually by
3552 3587 # using the key bound to 'possible-completions' (Control-l by default) or by
3553 3588 # hitting TAB twice. Turning this on makes the printing happen at the first
3554 3589 # TAB.
3555 3590 readline_parse_and_bind set show-all-if-ambiguous on
3556 3591
3557 3592 # If you have TAB set to complete names, you can rebind any key (Control-o by
3558 3593 # default) to insert a true TAB character.
3559 3594 readline_parse_and_bind "\C-o": tab-insert
3560 3595
3561 3596 # These commands allow you to indent/unindent easily, with the 4-space
3562 3597 # convention of the Python coding standards. Since IPython's internal
3563 3598 # auto-indent system also uses 4 spaces, you should not change the number of
3564 3599 # spaces in the code below.
3565 3600 readline_parse_and_bind "\M-i": " "
3566 3601 readline_parse_and_bind "\M-o": "\d\d\d\d"
3567 3602 readline_parse_and_bind "\M-I": "\d\d\d\d"
3568 3603
3569 3604 # Bindings for incremental searches in the history. These searches use the
3570 3605 # string typed so far on the command line and search anything in the previous
3571 3606 # input history containing them.
3572 3607 readline_parse_and_bind "\C-r": reverse-search-history
3573 3608 readline_parse_and_bind "\C-s": forward-search-history
3574 3609
3575 3610 # Bindings for completing the current line in the history of previous
3576 3611 # commands. This allows you to recall any previous command by typing its first
3577 3612 # few letters and hitting Control-p, bypassing all intermediate commands which
3578 3613 # may be in the history (much faster than hitting up-arrow 50 times!)
3579 3614 readline_parse_and_bind "\C-p": history-search-backward
3580 3615 readline_parse_and_bind "\C-n": history-search-forward
3581 3616
3582 3617 # I also like to have the same functionality on the plain arrow keys. If you'd
3583 3618 # rather have the arrows use all the history (and not just match what you've
3584 3619 # typed so far), comment out or delete the next two lines.
3585 3620 readline_parse_and_bind "\e[A": history-search-backward
3586 3621 readline_parse_and_bind "\e[B": history-search-forward
3587 3622
3588 3623 # These are typically on by default under *nix, but not win32.
3589 3624 readline_parse_and_bind "\C-k": kill-line
3590 3625 readline_parse_and_bind "\C-u": unix-line-discard
3591 3626
3592 3627 # (ii) readline_remove_delims: a string of characters to be removed from the
3593 3628 # default word-delimiters list used by readline, so that completions may be
3594 3629 # performed on strings which contain them.
3595 3630
3596 3631 readline_remove_delims -/~
3597 3632
3598 3633 # (iii) readline_merge_completions: whether to merge the result of all
3599 3634 # possible completions or not. If true, IPython will complete filenames,
3600 3635 # python names and aliases and return all possible completions. If you set it
3601 3636 # to false, each completer is used at a time, and only if it doesn't return
3602 3637 # any completions is the next one used.
3603 3638
3604 3639 # The default order is: [python_matches, file_matches, alias_matches]
3605 3640
3606 3641 readline_merge_completions 1
3607 3642
3608 3643 # (iv) readline_omit__names: normally hitting <tab> after a '.' in a name
3609 3644 # will complete all attributes of an object, including all the special methods
3610 3645 # whose names start with single or double underscores (like __getitem__ or
3611 3646 # __class__).
3612 3647
3613 3648 # This variable allows you to control this completion behavior:
3614 3649
3615 3650 # readline_omit__names 1 -> completion will omit showing any names starting
3616 3651 # with two __, but it will still show names starting with one _.
3617 3652
3618 3653 # readline_omit__names 2 -> completion will omit all names beginning with one
3619 3654 # _ (which obviously means filtering out the double __ ones).
3620 3655
3621 3656 # Even when this option is set, you can still see those names by explicitly
3622 3657 # typing a _ after the period and hitting <tab>: 'name._<tab>' will always
3623 3658 # complete attribute names starting with '_'.
3624 3659
3625 3660 # This option is off by default so that new users see all attributes of any
3626 3661 # objects they are dealing with.
3627 3662
3628 3663 readline_omit__names 0
3629 3664
3630 3665 #---------------------------------------------------------------------------
3631 3666 # Section: modules to be loaded with 'import ...'
3632 3667
3633 3668 # List, separated by spaces, the names of the modules you want to import
3634 3669
3635 3670 # Example:
3636 3671 # import_mod sys os
3637 3672 # will produce internally the statements
3638 3673 # import sys
3639 3674 # import os
3640 3675
3641 3676 # Each import is executed in its own try/except block, so if one module
3642 3677 # fails to load the others will still be ok.
3643 3678
3644 3679 import_mod
3645 3680
3646 3681 #---------------------------------------------------------------------------
3647 3682 # Section: modules to import some functions from: 'from ... import ...'
3648 3683
3649 3684 # List, one per line, the modules for which you want only to import some
3650 3685 # functions. Give the module name first and then the name of functions to be
3651 3686 # imported from that module.
3652 3687
3653 3688 # Example:
3654 3689
3655 3690 # import_some IPython.genutils timing timings
3656 3691 # will produce internally the statement
3657 3692 # from IPython.genutils import timing, timings
3658 3693
3659 3694 # timing() and timings() are two IPython utilities for timing the execution of
3660 3695 # your own functions, which you may find useful. Just commment out the above
3661 3696 # line if you want to test them.
3662 3697
3663 3698 # If you have more than one modules_some line, each gets its own try/except
3664 3699 # block (like modules, see above).
3665 3700
3666 3701 import_some
3667 3702
3668 3703 #---------------------------------------------------------------------------
3669 3704 # Section: modules to import all from : 'from ... import *'
3670 3705
3671 3706 # List (same syntax as import_mod above) those modules for which you want to
3672 3707 # import all functions. Remember, this is a potentially dangerous thing to do,
3673 3708 # since it is very easy to overwrite names of things you need. Use with
3674 3709 # caution.
3675 3710
3676 3711 # Example:
3677 3712 # import_all sys os
3678 3713 # will produce internally the statements
3679 3714 # from sys import *
3680 3715 # from os import *
3681 3716
3682 3717 # As before, each will be called in a separate try/except block.
3683 3718
3684 3719 import_all
3685 3720
3686 3721 #---------------------------------------------------------------------------
3687 3722 # Section: Python code to execute.
3688 3723
3689 3724 # Put here code to be explicitly executed (keep it simple!)
3690 3725 # Put one line of python code per line. All whitespace is removed (this is a
3691 3726 # feature, not a bug), so don't get fancy building loops here.
3692 3727 # This is just for quick convenient creation of things you want available.
3693 3728
3694 3729 # Example:
3695 3730 # execute x = 1
3696 3731 # execute print 'hello world'; y = z = 'a'
3697 3732 # will produce internally
3698 3733 # x = 1
3699 3734 # print 'hello world'; y = z = 'a'
3700 3735 # and each *line* (not each statement, we don't do python syntax parsing) is
3701 3736 # executed in its own try/except block.
3702 3737
3703 3738 execute
3704 3739
3705 3740 # Note for the adventurous: you can use this to define your own names for the
3706 3741 # magic functions, by playing some namespace tricks:
3707 3742
3708 3743 # execute __IPYTHON__.magic_pf = __IPYTHON__.magic_profile
3709 3744
3710 3745 # defines %pf as a new name for %profile.
3711 3746
3712 3747 #---------------------------------------------------------------------------
3713 3748 # Section: Pyhton files to load and execute.
3714 3749
3715 3750 # Put here the full names of files you want executed with execfile(file). If
3716 3751 # you want complicated initialization, just write whatever you want in a
3717 3752 # regular python file and load it from here.
3718 3753
3719 3754 # Filenames defined here (which *must* include the extension) are searched for
3720 3755 # through all of sys.path. Since IPython adds your .ipython directory to
3721 3756 # sys.path, they can also be placed in your .ipython dir and will be
3722 3757 # found. Otherwise (if you want to execute things not in .ipyton nor in
3723 3758 # sys.path) give a full path (you can use ~, it gets expanded)
3724 3759
3725 3760 # Example:
3726 3761 # execfile file1.py ~/file2.py
3727 3762 # will generate
3728 3763 # execfile('file1.py')
3729 3764 # execfile('_path_to_your_home/file2.py')
3730 3765
3731 3766 # As before, each file gets its own try/except block.
3732 3767
3733 3768 execfile
3734 3769
3735 3770 # If you are feeling adventurous, you can even add functionality to IPython
3736 3771 # through here. IPython works through a global variable called __ip which
3737 3772 # exists at the time when these files are read. If you know what you are doing
3738 3773 # (read the source) you can add functions to __ip in files loaded here.
3739 3774
3740 3775 # The file example-magic.py contains a simple but correct example. Try it:
3741 3776
3742 3777 # execfile example-magic.py
3743 3778
3744 3779 # Look at the examples in IPython/iplib.py for more details on how these magic
3745 3780 # functions need to process their arguments.
3746 3781
3747 3782 #---------------------------------------------------------------------------
3748 3783 # Section: aliases for system shell commands
3749 3784
3750 3785 # Here you can define your own names for system commands. The syntax is
3751 3786 # similar to that of the builtin %alias function:
3752 3787
3753 3788 # alias alias_name command_string
3754 3789
3755 3790 # The resulting aliases are auto-generated magic functions (hence usable as
3756 3791 # %alias_name)
3757 3792
3758 3793 # For example:
3759 3794
3760 3795 # alias myls ls -la
3761 3796
3762 3797 # will define 'myls' as an alias for executing the system command 'ls -la'.
3763 3798 # This allows you to customize IPython's environment to have the same aliases
3764 3799 # you are accustomed to from your own shell.
3765 3800
3766 3801 # You can also define aliases with parameters using %s specifiers (one per
3767 3802 # parameter):
3768 3803
3769 3804 # alias parts echo first %s second %s
3770 3805
3771 3806 # will give you in IPython:
3772 3807 # >>> %parts A B
3773 3808 # first A second B
3774 3809
3775 3810 # Use one 'alias' statement per alias you wish to define.
3776 3811
3777 3812 # alias
3778 3813
3779 3814 #************************* end of file <ipythonrc> ************************
3780
3815
3816
3817 ipy_user_conf.py
3818 ----------------
3819
3820 There should be a simple template ipy_user_conf.py file in your
3821 ~/.ipython directory. It is a plain python module that is imported
3822 during IPython startup, so you can do pretty much what you want there
3823 - import modules, configure extensions, change options, define magic
3824 commands, put variables and functions in the IPython namespace,
3825 etc. You use the IPython extension api object, acquired by
3826 IPython.ipapi.get() and documented in the "IPython extension API"
3827 chapter, to interact with IPython. A sample ipy_user_conf.py is listed
3828 below for reference::
3829
3830 # Most of your config files and extensions will probably start
3831 # with this import
3832
3833 import IPython.ipapi
3834 ip = IPython.ipapi.get()
3835
3836 # You probably want to uncomment this if you did %upgrade -nolegacy
3837 # import ipy_defaults
3838
3839 import os
3840
3841 def main():
3842
3843 #ip.dbg.debugmode = True
3844 ip.dbg.debug_stack()
3845
3846 # uncomment if you want to get ipython -p sh behaviour
3847 # without having to use command line switches
3848 import ipy_profile_sh
3849 import jobctrl
3850
3851 # Configure your favourite editor?
3852 # Good idea e.g. for %edit os.path.isfile
3853
3854 #import ipy_editors
3855
3856 # Choose one of these:
3857
3858 #ipy_editors.scite()
3859 #ipy_editors.scite('c:/opt/scite/scite.exe')
3860 #ipy_editors.komodo()
3861 #ipy_editors.idle()
3862 # ... or many others, try 'ipy_editors??' after import to see them
3863
3864 # Or roll your own:
3865 #ipy_editors.install_editor("c:/opt/jed +$line $file")
3866
3867
3868 o = ip.options
3869 # An example on how to set options
3870 #o.autocall = 1
3871 o.system_verbose = 0
3872
3873 #import_all("os sys")
3874 #execf('~/_ipython/ns.py')
3875
3876
3877 # -- prompt
3878 # A different, more compact set of prompts from the default ones, that
3879 # always show your current location in the filesystem:
3880
3881 #o.prompt_in1 = r'\C_LightBlue[\C_LightCyan\Y2\C_LightBlue]\C_Normal\n\C_Green|\#>'
3882 #o.prompt_in2 = r'.\D: '
3883 #o.prompt_out = r'[\#] '
3884
3885 # Try one of these color settings if you can't read the text easily
3886 # autoexec is a list of IPython commands to execute on startup
3887 #o.autoexec.append('%colors LightBG')
3888 #o.autoexec.append('%colors NoColor')
3889 o.autoexec.append('%colors Linux')
3890
3891
3892 # some config helper functions you can use
3893 def import_all(modules):
3894 """ Usage: import_all("os sys") """
3895 for m in modules.split():
3896 ip.ex("from %s import *" % m)
3897
3898 def execf(fname):
3899 """ Execute a file in user namespace """
3900 ip.ex('execfile("%s")' % os.path.expanduser(fname))
3901
3902 main()
3903
3781 3904
3782 3905
3783 3906 Fine-tuning your prompt
3784 3907 -----------------------
3785 3908
3786 3909 IPython's prompts can be customized using a syntax similar to that of
3787 3910 the bash shell. Many of bash's escapes are supported, as well as a few
3788 additional ones. We list them below:
3789
3790 *\#*
3791 the prompt/history count number. This escape is automatically
3792 wrapped in the coloring codes for the currently active color scheme.
3793 *\N*
3794 the 'naked' prompt/history count number: this is just the number
3795 itself, without any coloring applied to it. This lets you produce
3796 numbered prompts with your own colors.
3797 *\D*
3798 the prompt/history count, with the actual digits replaced by dots.
3799 Used mainly in continuation prompts (prompt_in2)
3800 *\w*
3801 the current working directory
3802 *\W*
3803 the basename of current working directory
3804 *\Xn*
3805 where $n=0\ldots5.$ The current working directory, with $HOME
3806 replaced by ~, and filtered out to contain only $n$ path elements
3807 *\Yn*
3808 Similar to \Xn, but with the $n+1$ element included if it is ~ (this
3809 is similar to the behavior of the %cn escapes in tcsh)
3810 *\u*
3811 the username of the current user
3812 *\$*
3813 if the effective UID is 0, a #, otherwise a $
3814 *\h*
3815 the hostname up to the first '.'
3816 *\H*
3817 the hostname
3818 *\n*
3819 a newline
3820 *\r*
3821 a carriage return
3822 *\v*
3823 IPython version string
3911 additional ones. We list them below::
3912
3913 \#
3914 the prompt/history count number. This escape is automatically
3915 wrapped in the coloring codes for the currently active color scheme.
3916 \N
3917 the 'naked' prompt/history count number: this is just the number
3918 itself, without any coloring applied to it. This lets you produce
3919 numbered prompts with your own colors.
3920 \D
3921 the prompt/history count, with the actual digits replaced by dots.
3922 Used mainly in continuation prompts (prompt_in2)
3923 \w
3924 the current working directory
3925 \W
3926 the basename of current working directory
3927 \Xn
3928 where $n=0\ldots5.$ The current working directory, with $HOME
3929 replaced by ~, and filtered out to contain only $n$ path elements
3930 \Yn
3931 Similar to \Xn, but with the $n+1$ element included if it is ~ (this
3932 is similar to the behavior of the %cn escapes in tcsh)
3933 \u
3934 the username of the current user
3935 \$
3936 if the effective UID is 0, a #, otherwise a $
3937 \h
3938 the hostname up to the first '.'
3939 \H
3940 the hostname
3941 \n
3942 a newline
3943 \r
3944 a carriage return
3945 \v
3946 IPython version string
3824 3947
3825 3948 In addition to these, ANSI color escapes can be insterted into the
3826 3949 prompts, as \C_ColorName. The list of valid color names is: Black, Blue,
3827 3950 Brown, Cyan, DarkGray, Green, LightBlue, LightCyan, LightGray,
3828 3951 LightGreen, LightPurple, LightRed, NoColor, Normal, Purple, Red, White,
3829 3952 Yellow.
3830 3953
3831 3954 Finally, IPython supports the evaluation of arbitrary expressions in
3832 3955 your prompt string. The prompt strings are evaluated through the syntax
3833 3956 of PEP 215, but basically you can use $x.y to expand the value of x.y,
3834 3957 and for more complicated expressions you can use braces: ${foo()+x} will
3835 3958 call function foo and add to it the value of x, before putting the
3836 3959 result into your prompt. For example, using
3837 3960 prompt_in1 '${commands.getoutput("uptime")}\nIn [\#]: '
3838 3961 will print the result of the uptime command on each prompt (assuming the
3839 3962 commands module has been imported in your ipythonrc file).
3840 3963
3841 3964
3842 3965 Prompt examples
3843 3966
3844 3967 The following options in an ipythonrc file will give you IPython's
3845 3968 default prompts::
3846 3969
3847 3970 prompt_in1 'In [\#]:'
3848 3971 prompt_in2 ' .\D.:'
3849 3972 prompt_out 'Out[\#]:'
3850 3973
3851 which look like this:
3974 which look like this::
3852 3975
3853 3976 In [1]: 1+2
3854 3977 Out[1]: 3
3855 3978
3856 3979 In [2]: for i in (1,2,3):
3857 3980 ...: print i,
3858 3981 ...:
3859 3982 1 2 3
3860 3983
3861 3984 These will give you a very colorful prompt with path information::
3862 3985
3863 3986 #prompt_in1 '\C_Red\u\C_Blue[\C_Cyan\Y1\C_Blue]\C_LightGreen\#>'
3864 3987 prompt_in2 ' ..\D>'
3865 3988 prompt_out '<\#>'
3866 3989
3867 3990 which look like this::
3868 3991
3869 3992 fperez[~/ipython]1> 1+2
3870 3993 <1> 3
3871 3994 fperez[~/ipython]2> for i in (1,2,3):
3872 3995 ...> print i,
3873 3996 ...>
3874 3997 1 2 3
3875 3998
3876 3999
3877 4000
3878 4001 IPython profiles
3879 4002 ----------------
3880 4003
3881 4004 As we already mentioned, IPython supports the -profile command-line
3882 4005 option (see sec. 5.2 <node5.html#sec:cmd-line-opts>). A profile is
3883 4006 nothing more than a particular configuration file like your basic
3884 4007 ipythonrc one, but with particular customizations for a specific
3885 4008 purpose. When you start IPython with 'ipython -profile <name>', it
3886 4009 assumes that in your IPYTHONDIR there is a file called ipythonrc-<name>,
3887 4010 and loads it instead of the normal ipythonrc.
3888 4011
3889 4012 This system allows you to maintain multiple configurations which load
3890 4013 modules, set options, define functions, etc. suitable for different
3891 4014 tasks and activate them in a very simple manner. In order to avoid
3892 4015 having to repeat all of your basic options (common things that don't
3893 4016 change such as your color preferences, for example), any profile can
3894 4017 include another configuration file. The most common way to use profiles
3895 4018 is then to have each one include your basic ipythonrc file as a starting
3896 4019 point, and then add further customizations.
3897 4020
3898 4021 In sections 11 <node11.html#sec:syntax-extensions> and 16
3899 4022 <node16.html#sec:Gnuplot> we discuss some particular profiles which come
3900 4023 as part of the standard IPython distribution. You may also look in your
3901 4024 IPYTHONDIR directory, any file whose name begins with ipythonrc- is a
3902 4025 profile. You can use those as examples for further customizations to
3903 4026 suit your own needs.
3904 4027
3905 4028 IPython as your default Python environment
3906 4029 ==========================================
3907 4030
3908 4031 Python honors the environment variable PYTHONSTARTUP and will execute at
3909 4032 startup the file referenced by this variable. If you put at the end of
3910 4033 this file the following two lines of code::
3911 4034
3912 4035 import IPython
3913 4036 IPython.Shell.IPShell().mainloop(sys_exit=1)
3914 4037
3915 4038 then IPython will be your working environment anytime you start Python.
3916 4039 The sys_exit=1 is needed to have IPython issue a call to sys.exit() when
3917 4040 it finishes, otherwise you'll be back at the normal Python '>>>'
3918 4041 prompt^4 <footnode.html#foot2368>.
3919 4042
3920 4043 This is probably useful to developers who manage multiple Python
3921 4044 versions and don't want to have correspondingly multiple IPython
3922 4045 versions. Note that in this mode, there is no way to pass IPython any
3923 4046 command-line options, as those are trapped first by Python itself.
3924 4047
3925 4048 Embedding IPython
3926 4049 =================
3927 4050
3928 4051 It is possible to start an IPython instance inside your own Python
3929 4052 programs. This allows you to evaluate dynamically the state of your
3930 4053 code, operate with your variables, analyze them, etc. Note however that
3931 4054 any changes you make to values while in the shell do not propagate back
3932 4055 to the running code, so it is safe to modify your values because you
3933 4056 won't break your code in bizarre ways by doing so.
3934 4057
3935 4058 This feature allows you to easily have a fully functional python
3936 4059 environment for doing object introspection anywhere in your code with a
3937 4060 simple function call. In some cases a simple print statement is enough,
3938 4061 but if you need to do more detailed analysis of a code fragment this
3939 4062 feature can be very valuable.
3940 4063
3941 4064 It can also be useful in scientific computing situations where it is
3942 4065 common to need to do some automatic, computationally intensive part and
3943 4066 then stop to look at data, plots, etc^5 <footnode.html#foot3206>.
3944 4067 Opening an IPython instance will give you full access to your data and
3945 4068 functions, and you can resume program execution once you are done with
3946 4069 the interactive part (perhaps to stop again later, as many times as
3947 4070 needed).
3948 4071
3949 4072 The following code snippet is the bare minimum you need to include in
3950 4073 your Python programs for this to work (detailed examples follow later)::
3951 4074
3952 4075 from IPython.Shell import IPShellEmbed
3953 4076
3954 4077 ipshell = IPShellEmbed()
3955 4078
3956 4079 ipshell() # this call anywhere in your program will start IPython
3957 4080
3958 4081 You can run embedded instances even in code which is itself being run at
3959 4082 the IPython interactive prompt with '%run <filename>'. Since it's easy
3960 4083 to get lost as to where you are (in your top-level IPython or in your
3961 4084 embedded one), it's a good idea in such cases to set the in/out prompts
3962 4085 to something different for the embedded instances. The code examples
3963 4086 below illustrate this.
3964 4087
3965 4088 You can also have multiple IPython instances in your program and open
3966 4089 them separately, for example with different options for data
3967 4090 presentation. If you close and open the same instance multiple times,
3968 4091 its prompt counters simply continue from each execution to the next.
3969 4092
3970 4093 Please look at the docstrings in the Shell.py module for more details on
3971 4094 the use of this system.
3972 4095
3973 4096 The following sample file illustrating how to use the embedding
3974 4097 functionality is provided in the examples directory as example-embed.py.
3975 4098 It should be fairly self-explanatory::
3976 4099
3977 4100
3978 4101 #!/usr/bin/env python
3979 4102
3980 4103 """An example of how to embed an IPython shell into a running program.
3981 4104
3982 4105 Please see the documentation in the IPython.Shell module for more details.
3983 4106
3984 4107 The accompanying file example-embed-short.py has quick code fragments for
3985 4108 embedding which you can cut and paste in your code once you understand how
3986 4109 things work.
3987 4110
3988 4111 The code in this file is deliberately extra-verbose, meant for learning."""
3989 4112
3990 4113 # The basics to get you going:
3991 4114
3992 4115 # IPython sets the __IPYTHON__ variable so you can know if you have nested
3993 4116 # copies running.
3994 4117
3995 4118 # Try running this code both at the command line and from inside IPython (with
3996 4119 # %run example-embed.py)
3997 4120 try:
3998 4121 __IPYTHON__
3999 4122 except NameError:
4000 4123 nested = 0
4001 4124 args = ['']
4002 4125 else:
4003 4126 print "Running nested copies of IPython."
4004 4127 print "The prompts for the nested copy have been modified"
4005 4128 nested = 1
4006 4129 # what the embedded instance will see as sys.argv:
4007 4130 args = ['-pi1','In <\\#>: ','-pi2',' .\\D.: ',
4008 4131 '-po','Out<\\#>: ','-nosep']
4009 4132
4010 4133 # First import the embeddable shell class
4011 4134 from IPython.Shell import IPShellEmbed
4012 4135
4013 4136 # Now create an instance of the embeddable shell. The first argument is a
4014 4137 # string with options exactly as you would type them if you were starting
4015 4138 # IPython at the system command line. Any parameters you want to define for
4016 4139 # configuration can thus be specified here.
4017 4140 ipshell = IPShellEmbed(args,
4018 4141 banner = 'Dropping into IPython',
4019 4142 exit_msg = 'Leaving Interpreter, back to program.')
4020 4143
4021 4144 # Make a second instance, you can have as many as you want.
4022 4145 if nested:
4023 4146 args[1] = 'In2<\\#>'
4024 4147 else:
4025 4148 args = ['-pi1','In2<\\#>: ','-pi2',' .\\D.: ',
4026 4149 '-po','Out<\\#>: ','-nosep']
4027 4150 ipshell2 = IPShellEmbed(args,banner = 'Second IPython instance.')
4028 4151
4029 4152 print '\nHello. This is printed from the main controller program.\n'
4030 4153
4031 4154 # You can then call ipshell() anywhere you need it (with an optional
4032 4155 # message):
4033 4156 ipshell('***Called from top level. '
4034 4157 'Hit Ctrl-D to exit interpreter and continue program.\n'
4035 4158 'Note that if you use %kill_embedded, you can fully deactivate\n'
4036 4159 'This embedded instance so it will never turn on again')
4037 4160
4038 4161 print '\nBack in caller program, moving along...\n'
4039 4162
4040 4163 #---------------------------------------------------------------------------
4041 4164 # More details:
4042 4165
4043 4166 # IPShellEmbed instances don't print the standard system banner and
4044 4167 # messages. The IPython banner (which actually may contain initialization
4045 4168 # messages) is available as <instance>.IP.BANNER in case you want it.
4046 4169
4047 4170 # IPShellEmbed instances print the following information everytime they
4048 4171 # start:
4049 4172
4050 4173 # - A global startup banner.
4051 4174
4052 4175 # - A call-specific header string, which you can use to indicate where in the
4053 4176 # execution flow the shell is starting.
4054 4177
4055 4178 # They also print an exit message every time they exit.
4056 4179
4057 4180 # Both the startup banner and the exit message default to None, and can be set
4058 4181 # either at the instance constructor or at any other time with the
4059 4182 # set_banner() and set_exit_msg() methods.
4060 4183
4061 4184 # The shell instance can be also put in 'dummy' mode globally or on a per-call
4062 4185 # basis. This gives you fine control for debugging without having to change
4063 4186 # code all over the place.
4064 4187
4065 4188 # The code below illustrates all this.
4066 4189
4067 4190
4068 4191 # This is how the global banner and exit_msg can be reset at any point
4069 4192 ipshell.set_banner('Entering interpreter - New Banner')
4070 4193 ipshell.set_exit_msg('Leaving interpreter - New exit_msg')
4071 4194
4072 4195 def foo(m):
4073 4196 s = 'spam'
4074 4197 ipshell('***In foo(). Try @whos, or print s or m:')
4075 4198 print 'foo says m = ',m
4076 4199
4077 4200 def bar(n):
4078 4201 s = 'eggs'
4079 4202 ipshell('***In bar(). Try @whos, or print s or n:')
4080 4203 print 'bar says n = ',n
4081 4204
4082 4205 # Some calls to the above functions which will trigger IPython:
4083 4206 print 'Main program calling foo("eggs")\n'
4084 4207 foo('eggs')
4085 4208
4086 4209 # The shell can be put in 'dummy' mode where calls to it silently return. This
4087 4210 # allows you, for example, to globally turn off debugging for a program with a
4088 4211 # single call.
4089 4212 ipshell.set_dummy_mode(1)
4090 4213 print '\nTrying to call IPython which is now "dummy":'
4091 4214 ipshell()
4092 4215 print 'Nothing happened...'
4093 4216 # The global 'dummy' mode can still be overridden for a single call
4094 4217 print '\nOverriding dummy mode manually:'
4095 4218 ipshell(dummy=0)
4096 4219
4097 4220 # Reactivate the IPython shell
4098 4221 ipshell.set_dummy_mode(0)
4099 4222
4100 4223 print 'You can even have multiple embedded instances:'
4101 4224 ipshell2()
4102 4225
4103 4226 print '\nMain program calling bar("spam")\n'
4104 4227 bar('spam')
4105 4228
4106 4229 print 'Main program finished. Bye!'
4107 4230
4108 4231 #********************** End of file <example-embed.py> ***********************
4109 4232
4110 4233 Once you understand how the system functions, you can use the following
4111 4234 code fragments in your programs which are ready for cut and paste::
4112 4235
4113 4236
4114 4237 """Quick code snippets for embedding IPython into other programs.
4115 4238
4116 4239 See example-embed.py for full details, this file has the bare minimum code for
4117 4240 cut and paste use once you understand how to use the system."""
4118 4241
4119 4242 #---------------------------------------------------------------------------
4120 4243 # This code loads IPython but modifies a few things if it detects it's running
4121 4244 # embedded in another IPython session (helps avoid confusion)
4122 4245
4123 4246 try:
4124 4247 __IPYTHON__
4125 4248 except NameError:
4126 4249 argv = ['']
4127 4250 banner = exit_msg = ''
4128 4251 else:
4129 4252 # Command-line options for IPython (a list like sys.argv)
4130 4253 argv = ['-pi1','In <\\#>:','-pi2',' .\\D.:','-po','Out<\\#>:']
4131 4254 banner = '*** Nested interpreter ***'
4132 4255 exit_msg = '*** Back in main IPython ***'
4133 4256
4134 4257 # First import the embeddable shell class
4135 4258 from IPython.Shell import IPShellEmbed
4136 4259 # Now create the IPython shell instance. Put ipshell() anywhere in your code
4137 4260 # where you want it to open.
4138 4261 ipshell = IPShellEmbed(argv,banner=banner,exit_msg=exit_msg)
4139 4262
4140 4263 #---------------------------------------------------------------------------
4141 4264 # This code will load an embeddable IPython shell always with no changes for
4142 4265 # nested embededings.
4143 4266
4144 4267 from IPython.Shell import IPShellEmbed
4145 4268 ipshell = IPShellEmbed()
4146 4269 # Now ipshell() will open IPython anywhere in the code.
4147 4270
4148 4271 #---------------------------------------------------------------------------
4149 4272 # This code loads an embeddable shell only if NOT running inside
4150 4273 # IPython. Inside IPython, the embeddable shell variable ipshell is just a
4151 4274 # dummy function.
4152 4275
4153 4276 try:
4154 4277 __IPYTHON__
4155 4278 except NameError:
4156 4279 from IPython.Shell import IPShellEmbed
4157 4280 ipshell = IPShellEmbed()
4158 4281 # Now ipshell() will open IPython anywhere in the code
4159 4282 else:
4160 4283 # Define a dummy ipshell() so the same code doesn't crash inside an
4161 4284 # interactive IPython
4162 4285 def ipshell(): pass
4163 4286
4164 4287 #******************* End of file <example-embed-short.py> ********************
4165 4288
4166 4289 Using the Python debugger (pdb)
4167 4290 ===============================
4168 4291
4169
4170 4292 Running entire programs via pdb
4171 4293 -------------------------------
4172 4294
4173 4295 pdb, the Python debugger, is a powerful interactive debugger which
4174 4296 allows you to step through code, set breakpoints, watch variables, etc.
4175 4297 IPython makes it very easy to start any script under the control of pdb,
4176 4298 regardless of whether you have wrapped it into a 'main()' function or
4177 4299 not. For this, simply type '%run -d myscript' at an IPython prompt. See
4178 4300 the %run command's documentation (via '%run?' or in Sec. 6.2
4179 4301 <node6.html#sec:magic>) for more details, including how to control where
4180 4302 pdb will stop execution first.
4181 4303
4182 4304 For more information on the use of the pdb debugger, read the included
4183 4305 pdb.doc file (part of the standard Python distribution). On a stock
4184 4306 Linux system it is located at /usr/lib/python2.3/pdb.doc, but the
4185 4307 easiest way to read it is by using the help() function of the pdb module
4186 4308 as follows (in an IPython prompt):
4187 4309
4188 4310 In [1]: import pdb
4189 4311 In [2]: pdb.help()
4190 4312
4191 4313 This will load the pdb.doc document in a file viewer for you automatically.
4192 4314
4193 4315
4194 4316 Automatic invocation of pdb on exceptions
4195 4317 -----------------------------------------
4196 4318
4197 4319 IPython, if started with the -pdb option (or if the option is set in
4198 4320 your rc file) can call the Python pdb debugger every time your code
4199 4321 triggers an uncaught exception^6 <footnode.html#foot2403>. This feature
4200 4322 can also be toggled at any time with the %pdb magic command. This can be
4201 4323 extremely useful in order to find the origin of subtle bugs, because pdb
4202 4324 opens up at the point in your code which triggered the exception, and
4203 4325 while your program is at this point 'dead', all the data is still
4204 4326 available and you can walk up and down the stack frame and understand
4205 4327 the origin of the problem.
4206 4328
4207 4329 Furthermore, you can use these debugging facilities both with the
4208 4330 embedded IPython mode and without IPython at all. For an embedded shell
4209 4331 (see sec. 9 <node9.html#sec:embed>), simply call the constructor with
4210 4332 '-pdb' in the argument string and automatically pdb will be called if an
4211 4333 uncaught exception is triggered by your code.
4212 4334
4213 4335 For stand-alone use of the feature in your programs which do not use
4214 4336 IPython at all, put the following lines toward the top of your 'main'
4215 routine:
4337 routine::
4216 4338
4217 import sys,IPython.ultraTB
4218 sys.excepthook = IPython.ultraTB.FormattedTB(mode='Verbose',
4219 color_scheme='Linux', call_pdb=1)
4339 import sys,IPython.ultraTB
4340 sys.excepthook = IPython.ultraTB.FormattedTB(mode='Verbose',
4341 color_scheme='Linux', call_pdb=1)
4220 4342
4221 4343 The mode keyword can be either 'Verbose' or 'Plain', giving either very
4222 4344 detailed or normal tracebacks respectively. The color_scheme keyword can
4223 4345 be one of 'NoColor', 'Linux' (default) or 'LightBG'. These are the same
4224 4346 options which can be set in IPython with -colors and -xmode.
4225 4347
4226 4348 This will give any of your programs detailed, colored tracebacks with
4227 4349 automatic invocation of pdb.
4228 4350
4229 4351
4230 4352 Extensions for syntax processing
4231 4353 ================================
4232 4354
4233 4355 This isn't for the faint of heart, because the potential for breaking
4234 4356 things is quite high. But it can be a very powerful and useful feature.
4235 4357 In a nutshell, you can redefine the way IPython processes the user input
4236 4358 line to accept new, special extensions to the syntax without needing to
4237 4359 change any of IPython's own code.
4238 4360
4239 4361 In the IPython/Extensions directory you will find some examples
4240 4362 supplied, which we will briefly describe now. These can be used 'as is'
4241 4363 (and both provide very useful functionality), or you can use them as a
4242 4364 starting point for writing your own extensions.
4243 4365
4244 4366
4245 Pasting of code starting with '»> ' or '... '
4367 Pasting of code starting with '>>> ' or '... '
4246 4368 ----------------------------------------------
4247 4369
4248 4370 In the python tutorial it is common to find code examples which have
4249 4371 been taken from real python sessions. The problem with those is that all
4250 4372 the lines begin with either '>>> ' or '... ', which makes it impossible
4251 4373 to paste them all at once. One must instead do a line by line manual
4252 4374 copying, carefully removing the leading extraneous characters.
4253 4375
4254 4376 This extension identifies those starting characters and removes them
4255 4377 from the input automatically, so that one can paste multi-line examples
4256 4378 directly into IPython, saving a lot of time. Please look at the file
4257 4379 InterpreterPasteInput.py in the IPython/Extensions directory for details
4258 4380 on how this is done.
4259 4381
4260 4382 IPython comes with a special profile enabling this feature, called
4261 4383 tutorial. Simply start IPython via 'ipython -p tutorial' and the feature
4262 4384 will be available. In a normal IPython session you can activate the
4263 4385 feature by importing the corresponding module with:
4264 4386 In [1]: import IPython.Extensions.InterpreterPasteInput
4265 4387
4266 4388 The following is a 'screenshot' of how things work when this extension
4267 4389 is on, copying an example from the standard tutorial::
4268 4390
4269 4391 IPython profile: tutorial
4270 4392
4271 4393 *** Pasting of code with ">>>" or "..." has been enabled.
4272 4394
4273 4395 In [1]: >>> def fib2(n): # return Fibonacci series up to n
4274 4396 ...: ... """Return a list containing the Fibonacci series up to
4275 4397 n."""
4276 4398 ...: ... result = []
4277 4399 ...: ... a, b = 0, 1
4278 4400 ...: ... while b < n:
4279 4401 ...: ... result.append(b) # see below
4280 4402 ...: ... a, b = b, a+b
4281 4403 ...: ... return result
4282 4404 ...:
4283 4405
4284 4406 In [2]: fib2(10)
4285 4407 Out[2]: [1, 1, 2, 3, 5, 8]
4286 4408
4287 4409 Note that as currently written, this extension does not recognize
4288 4410 IPython's prompts for pasting. Those are more complicated, since the
4289 4411 user can change them very easily, they involve numbers and can vary in
4290 4412 length. One could however extract all the relevant information from the
4291 4413 IPython instance and build an appropriate regular expression. This is
4292 4414 left as an exercise for the reader.
4293 4415
4294 4416
4295 4417 Input of physical quantities with units
4296 4418 ---------------------------------------
4297 4419
4298 4420 The module PhysicalQInput allows a simplified form of input for physical
4299 4421 quantities with units. This file is meant to be used in conjunction with
4300 4422 the PhysicalQInteractive module (in the same directory) and
4301 4423 Physics.PhysicalQuantities from Konrad Hinsen's ScientificPython
4302 4424 (http://dirac.cnrs-orleans.fr/ScientificPython/).
4303 4425
4304 4426 The Physics.PhysicalQuantities module defines PhysicalQuantity objects,
4305 4427 but these must be declared as instances of a class. For example, to
4306 4428 define v as a velocity of 3 m/s, normally you would write::
4429
4307 4430 In [1]: v = PhysicalQuantity(3,'m/s')
4308 4431
4309 4432 Using the PhysicalQ_Input extension this can be input instead as:
4310 4433 In [1]: v = 3 m/s
4311 4434 which is much more convenient for interactive use (even though it is
4312 4435 blatantly invalid Python syntax).
4313 4436
4314 4437 The physics profile supplied with IPython (enabled via 'ipython -p
4315 4438 physics') uses these extensions, which you can also activate with:
4316 4439
4317 4440 from math import * # math MUST be imported BEFORE PhysicalQInteractive
4318 4441 from IPython.Extensions.PhysicalQInteractive import *
4319 4442 import IPython.Extensions.PhysicalQInput
4320 4443
4321 IPython as a system shell
4322 =========================
4323 4444
4324 IPython ships with a special profile called pysh, which you can activate
4325 at the command line as 'ipython -p pysh'. This loads InterpreterExec,
4326 along with some additional facilities and a prompt customized for
4327 filesystem navigation.
4445 IPython as a system shell - the 'Sh' profile
4446 ============================================
4447
4448 The 'sh' profile optimizes IPython for system shell usage. Apart from
4449 certain job control functionality that is present in unix (ctrl+z does
4450 "suspend"), the sh profile should provide you with most of the
4451 functionality you use daily in system shell, and more. Invoke IPython
4452 in 'sh' profile by doing 'ipython -p sh', or (in win32) by launching
4453 the "pysh" shortcut in start menu.
4454
4455 If you want to use the features of sh profile as your defaults (which
4456 might be a good idea if you use other profiles a lot of the time but
4457 still want the convenience of sh profile), add ``import ipy_profile_sh``
4458 to your ~/.ipython/ipy_user_conf.py.
4459
4460 The 'sh' profile is different from the default profile in that:
4328 4461
4329 Note that this does not make IPython a full-fledged system shell. In
4330 particular, it has no job control, so if you type Ctrl-Z (under Unix),
4331 you'll suspend pysh itself, not the process you just started.
4462 * Prompt shows the current directory
4463 * Spacing between prompts and input is more compact (no padding with
4464 empty lines). The startup banner is more compact as well.
4465 * System commands are directly available (in alias table) without
4466 requesting %rehashx - however, if you install new programs along
4467 your PATH, you might want to run %rehashx to update the persistent
4468 alias table
4469 * Macros are stored in raw format by default. That is, instead of
4470 '_ip.system("cat foo"), the macro will contain text 'cat foo')
4471 * Autocall is in full mode
4472 * Calling "up" does "cd .."
4332 4473
4333 What the shell profile allows you to do is to use the convenient and
4334 powerful syntax of Python to do quick scripting at the command line.
4335 Below we describe some of its features.
4474 The 'sh' profile is different from the now-obsolete (and unavailable)
4475 'pysh' profile in that:
4336 4476
4477 * '$$var = command' and '$var = command' syntax is not supported
4478 * anymore. Use 'var = !command' instead (incidentally, this is
4479 * available in all IPython profiles). Note that !!command *will*
4480 * work.
4337 4481
4338 4482 Aliases
4339 4483 -------
4340 4484
4341 4485 All of your $PATH has been loaded as IPython aliases, so you should be
4342 able to type any normal system command and have it executed. See %alias?
4343 and %unalias? for details on the alias facilities. See also %rehash? and
4486 able to type any normal system command and have it executed. See
4487 %alias? and %unalias? for details on the alias facilities. See also
4344 4488 %rehashx? for details on the mechanism used to load $PATH.
4345 4489
4346 4490
4347 Special syntax
4348 --------------
4491 Directory management
4492 --------------------
4493
4494 Since each command passed by ipython to the underlying system is executed
4495 in a subshell which exits immediately, you can NOT use !cd to navigate
4496 the filesystem.
4349 4497
4350 Any lines which begin with '~', '/' and '.' will be executed as shell
4351 commands instead of as Python code. The special escapes below are also
4352 recognized. !cmd is valid in single or multi-line input, all others are
4353 only valid in single-line input::
4498 IPython provides its own builtin '%cd' magic command to move in the
4499 filesystem (the % is not required with automagic on). It also maintains
4500 a list of visited directories (use %dhist to see it) and allows direct
4501 switching to any of them. Type 'cd?' for more details.
4354 4502
4355 *!cmd*
4356 pass 'cmd' directly to the shell
4357 *!!cmd*
4358 execute 'cmd' and return output as a list (split on '\n')
4359 *var=!cmd
4360 capture output of cmd into var, as a string list
4503 %pushd, %popd and %dirs are provided for directory stack handling.
4361 4504
4362 The $/$$ syntaxes make Python variables from system output, which you
4363 can later use for further scripting. The converse is also possible: when
4364 executing an alias or calling to the system via !/!!, you can expand any
4365 python variable or expression by prepending it with $. Full details of
4366 the allowed syntax can be found in Python's PEP 215.
4367 4505
4368 A few brief examples will illustrate these (note that the indentation
4369 below may be incorrectly displayed)::
4506 Enabled extensions
4507 ------------------
4370 4508
4371 fperez[~/test]|3> !ls *s.py
4372 scopes.py strings.py
4509 Some extensions, listed below, are enabled as default in this profile.
4373 4510
4374 ls is an internal alias, so there's no need to use !::
4511 envpersist
4512 ++++++++++
4375 4513
4376 fperez[~/test]|4> ls *s.py
4377 scopes.py* strings.py
4514 %env can be used to "remember" environment variable manipulations. Examples::
4378 4515
4379 !!ls will return the output into a Python variable FIXME!!!::
4516 %env - Show all environment variables
4517 %env VISUAL=jed - set VISUAL to jed
4518 %env PATH+=;/foo - append ;foo to PATH
4519 %env PATH+=;/bar - also append ;bar to PATH
4520 %env PATH-=/wbin; - prepend /wbin; to PATH
4521 %env -d VISUAL - forget VISUAL persistent val
4522 %env -p - print all persistent env modifications
4380 4523
4381 fperez[~/test]|5> !!ls *s.py
4382 <5> ['scopes.py', 'strings.py']
4383 fperez[~/test]|6> print _5
4384 ['scopes.py', 'strings.py']
4524 ipy_which
4525 +++++++++
4385 4526
4386 $ and $$ allow direct capture to named variables:
4527 %which magic command. Like 'which' in unix, but knows about ipython aliases.
4387 4528
4388 fperez[~/test]|7> $astr = ls *s.py
4389 fperez[~/test]|8> astr
4390 <8> 'scopes.py\nstrings.py'
4529 Example::
4391 4530
4392 fperez[~/test]|9> $$alist = ls *s.py
4393 fperez[~/test]|10> alist
4394 <10> ['scopes.py', 'strings.py']
4531 [C:/ipython]|14> %which st
4532 st -> start .
4533 [C:/ipython]|15> %which d
4534 d -> dir /w /og /on
4535 [C:/ipython]|16> %which cp
4536 cp -> cp
4537 == c:\bin\cp.exe
4538 c:\bin\cp.exe
4395 4539
4396 alist is now a normal python list you can loop over. Using $ will expand
4397 back the python values when alias calls are made:
4540 ipy_app_completers
4541 ++++++++++++++++++
4398 4542
4399 fperez[~/test]|11> for f in alist:
4400 |..> print 'file',f,
4401 |..> wc -l $f
4402 |..>
4403 file scopes.py 13 scopes.py
4404 file strings.py 4 strings.py
4543 Custom tab completers for some apps like svn, hg, bzr, apt-get. Try 'apt-get install <TAB>' in debian/ubuntu.
4405 4544
4406 Note that you may need to protect your variables with braces if you want
4407 to append strings to their names. To copy all files in alist to .bak
4408 extensions, you must use::
4545 ipy_rehashdir
4546 +++++++++++++
4409 4547
4410 fperez[~/test]|12> for f in alist:
4411 |..> cp $f ${f}.bak
4548 Allows you to add system command aliases for commands that are not along your path. Let's say that you just installed Putty and want to be able to invoke it without adding it to path, you can create the alias for it with rehashdir::
4412 4549
4413 If you try using $f.bak, you'll get an AttributeError exception saying
4414 that your string object doesn't have a .bak attribute. This is because
4415 the $ expansion mechanism allows you to expand full Python expressions::
4550 [~]|22> cd c:/opt/PuTTY/
4551 [c:opt/PuTTY]|23> rehashdir .
4552 <23> ['pageant', 'plink', 'pscp', 'psftp', 'putty', 'puttygen', 'unins000']
4416 4553
4417 fperez[~/test]|13> echo "sys.platform is: $sys.platform"
4418 sys.platform is: linux2
4554 Now, you can execute any of those commams directly::
4419 4555
4420 IPython's input history handling is still active, which allows you to
4421 rerun a single block of multi-line input by simply using exec::
4556 [c:opt/PuTTY]|24> cd
4557 [~]|25> putty
4422 4558
4423 fperez[~/test]|14> $$alist = ls *.eps
4424 fperez[~/test]|15> exec _i11
4425 file image2.eps 921 image2.eps
4426 file image.eps 921 image.eps
4559 (the putty window opens).
4427 4560
4428 While these are new special-case syntaxes, they are designed to allow
4429 very efficient use of the shell with minimal typing. At an interactive
4430 shell prompt, conciseness of expression wins over readability.
4561 If you want to store the alias so that it will always be available, do '%store putty'. If you want to %store all these aliases persistently, just do it in a for loop::
4431 4562
4563 [~]|27> for a in _23:
4564 |..> %store $a
4565 |..>
4566 |..>
4567 Alias stored: pageant (0, 'c:\\opt\\PuTTY\\pageant.exe')
4568 Alias stored: plink (0, 'c:\\opt\\PuTTY\\plink.exe')
4569 Alias stored: pscp (0, 'c:\\opt\\PuTTY\\pscp.exe')
4570 Alias stored: psftp (0, 'c:\\opt\\PuTTY\\psftp.exe')
4571 ...
4432 4572
4433 Useful functions and modules
4434 ----------------------------
4573 mglob
4574 +++++
4435 4575
4436 The os, sys and shutil modules from the Python standard library are
4437 automatically loaded. Some additional functions, useful for shell usage,
4438 are listed below. You can request more help about them with '?'.
4576 Provide the magic function %mglob, which makes it easier (than the 'find' command) to collect (possibly recursive) file lists. Examples::
4439 4577
4440 *shell*
4441 - execute a command in the underlying system shell
4442 *system*
4443 - like shell(), but return the exit status of the command
4444 *sout*
4445 - capture the output of a command as a string
4446 *lout*
4447 - capture the output of a command as a list (split on '\n')
4448 *getoutputerror*
4449 - capture (output,error) of a shell commandss
4578 [c:/ipython]|9> mglob *.py
4579 [c:/ipython]|10> mglob *.py rec:*.txt
4580 [c:/ipython]|19> workfiles = %mglob !.svn/ !.hg/ !*_Data/ !*.bak rec:.
4450 4581
4451 sout/lout are the functional equivalents of $/$$. They are provided to
4452 allow you to capture system output in the middle of true python code,
4453 function definitions, etc (where $ and $$ are invalid).
4582 Note that the first 2 calls will put the file list in result history (_, _9, _10), and the last one will assign it to 'workfiles'.
4454 4583
4455 4584
4456 Directory management
4585 Prompt customization
4457 4586 --------------------
4458 4587
4459 Since each command passed by pysh to the underlying system is executed
4460 in a subshell which exits immediately, you can NOT use !cd to navigate
4461 the filesystem.
4588 The sh profile uses the following prompt configurations::
4462 4589
4463 Pysh provides its own builtin '%cd' magic command to move in the
4464 filesystem (the % is not required with automagic on). It also maintains
4465 a list of visited directories (use %dhist to see it) and allows direct
4466 switching to any of them. Type 'cd?' for more details.
4590 o.prompt_in1= r'\C_LightBlue[\C_LightCyan\Y2\C_LightBlue]\C_Green|\#>'
4591 o.prompt_in2= r'\C_Green|\C_LightGreen\D\C_Green>'
4467 4592
4468 %pushd, %popd and %dirs are provided for directory stack handling.
4593 You can change the prompt configuration to your liking by editing
4594 ipy_user_conf.py.
4595
4596 String lists
4597 ============
4598
4599 String lists (IPython.genutils.SList) are handy way to process output
4600 from system commands. They are produced by ``var = !cmd`` syntax.
4469 4601
4602 First, we acquire the output of 'ls -l'::
4470 4603
4471 Prompt customization
4604 [Q:doc/examples]|2> lines = !ls -l
4605 ==
4606 ['total 23',
4607 '-rw-rw-rw- 1 ville None 1163 Sep 30 2006 example-demo.py',
4608 '-rw-rw-rw- 1 ville None 1927 Sep 30 2006 example-embed-short.py',
4609 '-rwxrwxrwx 1 ville None 4606 Sep 1 17:15 example-embed.py',
4610 '-rwxrwxrwx 1 ville None 1017 Sep 30 2006 example-gnuplot.py',
4611 '-rwxrwxrwx 1 ville None 339 Jun 11 18:01 extension.py',
4612 '-rwxrwxrwx 1 ville None 113 Dec 20 2006 seteditor.py',
4613 '-rwxrwxrwx 1 ville None 245 Dec 12 2006 seteditor.pyc']
4472 4614
4473 The supplied ipythonrc-pysh profile comes with an example of a very
4474 colored and detailed prompt, mainly to serve as an illustration. The
4475 valid escape sequences, besides color names, are:
4615 Now, let's take a look at the contents of 'lines' (the first number is
4616 the list element number)::
4476 4617
4477 *\#*
4478 - Prompt number, wrapped in the color escapes for the input prompt
4479 (determined by the current color scheme).
4480 *\N*
4481 - Just the prompt counter number, without any coloring wrappers. You
4482 can thus customize the actual prompt colors manually.
4483 *\D*
4484 - Dots, as many as there are digits in \# (so they align).
4485 *\w*
4486 - Current working directory (cwd).
4487 *\W*
4488 - Basename of current working directory.
4489 *\XN*
4490 - Where N=0..5. N terms of the cwd, with $HOME written as ~.
4491 *\YN*
4492 - Where N=0..5. Like XN, but if ~ is term N+1 it's also shown.
4493 *\u*
4494 - Username.
4495 *\H*
4496 - Full hostname.
4497 *\h*
4498 - Hostname up to first '.'
4499 *\$*
4500 - Root symbol ($ or #).
4501 *\t*
4502 - Current time, in H:M:S format.
4503 *\v*
4504 - IPython release version.
4505 *\n*
4506 - Newline.
4507 *\r*
4508 - Carriage return.
4509 *\\*
4510 - An explicitly escaped '\'.
4618 [Q:doc/examples]|3> lines
4619 <3> SList (.p, .n, .l, .s, .grep(), .fields() available). Value:
4511 4620
4512 You can configure your prompt colors using any ANSI color escape. Each
4513 color escape sets the color for any subsequent text, until another
4514 escape comes in and changes things. The valid color escapes are:
4621 0: total 23
4622 1: -rw-rw-rw- 1 ville None 1163 Sep 30 2006 example-demo.py
4623 2: -rw-rw-rw- 1 ville None 1927 Sep 30 2006 example-embed-short.py
4624 3: -rwxrwxrwx 1 ville None 4606 Sep 1 17:15 example-embed.py
4625 4: -rwxrwxrwx 1 ville None 1017 Sep 30 2006 example-gnuplot.py
4626 5: -rwxrwxrwx 1 ville None 339 Jun 11 18:01 extension.py
4627 6: -rwxrwxrwx 1 ville None 113 Dec 20 2006 seteditor.py
4628 7: -rwxrwxrwx 1 ville None 245 Dec 12 2006 seteditor.pyc
4515 4629
4516 *\C_Black*
4630 Now, let's filter out the 'embed' lines::
4517 4631
4518 *\C_Blue*
4632 [Q:doc/examples]|4> l2 = lines.grep('embed',prune=1)
4633 [Q:doc/examples]|5> l2
4634 <5> SList (.p, .n, .l, .s, .grep(), .fields() available). Value:
4519 4635
4520 *\C_Brown*
4636 0: total 23
4637 1: -rw-rw-rw- 1 ville None 1163 Sep 30 2006 example-demo.py
4638 2: -rwxrwxrwx 1 ville None 1017 Sep 30 2006 example-gnuplot.py
4639 3: -rwxrwxrwx 1 ville None 339 Jun 11 18:01 extension.py
4640 4: -rwxrwxrwx 1 ville None 113 Dec 20 2006 seteditor.py
4641 5: -rwxrwxrwx 1 ville None 245 Dec 12 2006 seteditor.pyc
4521 4642
4522 *\C_Cyan*
4643 Now, we want strings having just file names and permissions::
4523 4644
4524 *\C_DarkGray*
4645 [Q:doc/examples]|6> l2.fields(8,0)
4646 <6> SList (.p, .n, .l, .s, .grep(), .fields() available). Value:
4525 4647
4526 *\C_Green*
4648 0: total
4649 1: example-demo.py -rw-rw-rw-
4650 2: example-gnuplot.py -rwxrwxrwx
4651 3: extension.py -rwxrwxrwx
4652 4: seteditor.py -rwxrwxrwx
4653 5: seteditor.pyc -rwxrwxrwx
4527 4654
4528 *\C_LightBlue*
4655 Note how the line with 'total' does not raise IndexError.
4529 4656
4530 *\C_LightCyan*
4657 If you want to split these (yielding lists), call fields() without
4658 arguments::
4531 4659
4532 *\C_LightGray*
4660 [Q:doc/examples]|7> _.fields()
4661 <7>
4662 [['total'],
4663 ['example-demo.py', '-rw-rw-rw-'],
4664 ['example-gnuplot.py', '-rwxrwxrwx'],
4665 ['extension.py', '-rwxrwxrwx'],
4666 ['seteditor.py', '-rwxrwxrwx'],
4667 ['seteditor.pyc', '-rwxrwxrwx']]
4533 4668
4534 *\C_LightGreen*
4669 If you want to pass these separated with spaces to a command (typical
4670 for lists if files), use the .s property::
4535 4671
4536 *\C_LightPurple*
4537 4672
4538 *\C_LightRed*
4673 [Q:doc/examples]|13> files = l2.fields(8).s
4674 [Q:doc/examples]|14> files
4675 <14> 'example-demo.py example-gnuplot.py extension.py seteditor.py seteditor.pyc'
4676 [Q:doc/examples]|15> ls $files
4677 example-demo.py example-gnuplot.py extension.py seteditor.py seteditor.pyc
4539 4678
4540 *\C_Purple*
4679 SLists are inherited from normal python lists, so every list method is
4680 available::
4541 4681
4542 *\C_Red*
4682 [Q:doc/examples]|21> lines.append('hey')
4543 4683
4544 *\C_White*
4545 4684
4546 *\C_Yellow*
4685 Real world example: remove all files outside version control
4686 ------------------------------------------------------------
4687
4688 First, capture output of "hg status"::
4689
4690 [Q:/ipython]|28> out = !hg status
4691 ==
4692 ['M IPython\\Extensions\\ipy_kitcfg.py',
4693 'M IPython\\Extensions\\ipy_rehashdir.py',
4694 ...
4695 '? build\\lib\\IPython\\Debugger.py',
4696 '? build\\lib\\IPython\\Extensions\\InterpreterExec.py',
4697 '? build\\lib\\IPython\\Extensions\\InterpreterPasteInput.py',
4698 ...
4699
4700 (lines starting with ? are not under version control).
4701
4702 ::
4703
4704 [Q:/ipython]|35> junk = out.grep(r'^\?').fields(1)
4705 [Q:/ipython]|36> junk
4706 <36> SList (.p, .n, .l, .s, .grep(), .fields() availab
4707 ...
4708 10: build\bdist.win32\winexe\temp\_ctypes.py
4709 11: build\bdist.win32\winexe\temp\_hashlib.py
4710 12: build\bdist.win32\winexe\temp\_socket.py
4711
4712 Now we can just remove these files by doing 'rm $junk.s'.
4713
4714 The .s, .n, .p properties
4715 -------------------------
4716
4717 The '.s' property returns one string where lines are separated by
4718 single space (for convenient passing to system commands). The '.n'
4719 property return one string where the lines are separated by '\n'
4720 (i.e. the original output of the function). If the items in string
4721 list are file names, '.p' can be used to get a list of "path" objects
4722 for convenient file manipulation.
4547 4723
4548 *\C_Normal*
4549 Stop coloring, defaults to your terminal settings.
4550 4724
4551 4725 Threading support
4552 4726 =================
4553 4727
4554 4728 WARNING: The threading support is still somewhat experimental, and it
4555 4729 has only seen reasonable testing under Linux. Threaded code is
4556 4730 particularly tricky to debug, and it tends to show extremely
4557 4731 platform-dependent behavior. Since I only have access to Linux machines,
4558 4732 I will have to rely on user's experiences and assistance for this area
4559 4733 of IPython to improve under other platforms.
4560 4734
4561 4735 IPython, via the -gthread , -qthread, -q4thread and -wthread options
4562 4736 (described in Sec. 5.1 <node5.html#sec:threading-opts>), can run in
4563 4737 multithreaded mode to support pyGTK, Qt3, Qt4 and WXPython applications
4564 4738 respectively. These GUI toolkits need to control the python main loop of
4565 4739 execution, so under a normal Python interpreter, starting a pyGTK, Qt3,
4566 4740 Qt4 or WXPython application will immediately freeze the shell.
4567 4741
4568 4742 IPython, with one of these options (you can only use one at a time),
4569 4743 separates the graphical loop and IPython's code execution run into
4570 4744 different threads. This allows you to test interactively (with %run, for
4571 4745 example) your GUI code without blocking.
4572 4746
4573 4747 A nice mini-tutorial on using IPython along with the Qt Designer
4574 4748 application is available at the SciPy wiki:
4575 4749 http://www.scipy.org/Cookbook/Matplotlib/Qt_with_IPython_and_Designer.
4576 4750
4577 4751
4578 4752 Tk issues
4579 4753 ---------
4580 4754
4581 4755 As indicated in Sec. 5.1 <node5.html#sec:threading-opts>, a special -tk
4582 4756 option is provided to try and allow Tk graphical applications to coexist
4583 4757 interactively with WX, Qt or GTK ones. Whether this works at all,
4584 4758 however, is very platform and configuration dependent. Please experiment
4585 4759 with simple test cases before committing to using this combination of Tk
4586 4760 and GTK/Qt/WX threading in a production environment.
4587 4761
4588 4762
4589 4763 I/O pitfalls
4590 4764 ------------
4591 4765
4592 4766 Be mindful that the Python interpreter switches between threads every
4593 4767 $N$ bytecodes, where the default value as of Python 2.3 is $N=100.$ This
4594 4768 value can be read by using the sys.getcheckinterval() function, and it
4595 4769 can be reset via sys.setcheckinterval(N). This switching of threads can
4596 4770 cause subtly confusing effects if one of your threads is doing file I/O.
4597 4771 In text mode, most systems only flush file buffers when they encounter a
4598 '\n'. An instruction as simple as
4772 '\n'. An instruction as simple as::
4773
4599 4774 print >> filehandle, ''hello world''
4775
4600 4776 actually consists of several bytecodes, so it is possible that the
4601 4777 newline does not reach your file before the next thread switch.
4602 4778 Similarly, if you are writing to a file in binary mode, the file won't
4603 4779 be flushed until the buffer fills, and your other thread may see
4604 4780 apparently truncated files.
4605 4781
4606 4782 For this reason, if you are using IPython's thread support and have (for
4607 4783 example) a GUI application which will read data generated by files
4608 4784 written to from the IPython thread, the safest approach is to open all
4609 4785 of your files in unbuffered mode (the third argument to the file/open
4610 4786 function is the buffering value)::
4787
4611 4788 filehandle = open(filename,mode,0)
4612 4789
4613 4790 This is obviously a brute force way of avoiding race conditions with the
4614 4791 file buffering. If you want to do it cleanly, and you have a resource
4615 4792 which is being shared by the interactive IPython loop and your GUI
4616 4793 thread, you should really handle it with thread locking and
4617 4794 syncrhonization properties. The Python documentation discusses these.
4618 4795
4619 4796 Interactive demos with IPython
4620 4797 ==============================
4621 4798
4622 4799 IPython ships with a basic system for running scripts interactively in
4623 4800 sections, useful when presenting code to audiences. A few tags embedded
4624 4801 in comments (so that the script remains valid Python code) divide a file
4625 4802 into separate blocks, and the demo can be run one block at a time, with
4626 4803 IPython printing (with syntax highlighting) the block before executing
4627 4804 it, and returning to the interactive prompt after each block. The
4628 4805 interactive namespace is updated after each block is run with the
4629 4806 contents of the demo's namespace.
4630 4807
4631 4808 This allows you to show a piece of code, run it and then execute
4632 4809 interactively commands based on the variables just created. Once you
4633 4810 want to continue, you simply execute the next block of the demo. The
4634 4811 following listing shows the markup necessary for dividing a script into
4635 4812 sections for execution as a demo::
4636 4813
4637 4814
4638 4815 """A simple interactive demo to illustrate the use of IPython's Demo class.
4639 4816
4640 4817 Any python script can be run as a demo, but that does little more than showing
4641 4818 it on-screen, syntax-highlighted in one shot. If you add a little simple
4642 4819 markup, you can stop at specified intervals and return to the ipython prompt,
4643 4820 resuming execution later.
4644 4821 """
4645 4822
4646 4823 print 'Hello, welcome to an interactive IPython demo.'
4647 4824 print 'Executing this block should require confirmation before proceeding,'
4648 4825 print 'unless auto_all has been set to true in the demo object'
4649 4826
4650 4827 # The mark below defines a block boundary, which is a point where IPython will
4651 4828 # stop execution and return to the interactive prompt.
4652 4829 # Note that in actual interactive execution,
4653 4830 # <demo> --- stop ---
4654 4831
4655 4832 x = 1
4656 4833 y = 2
4657 4834
4658 4835 # <demo> --- stop ---
4659 4836
4660 4837 # the mark below makes this block as silent
4661 4838 # <demo> silent
4662 4839
4663 4840 print 'This is a silent block, which gets executed but not printed.'
4664 4841
4665 4842 # <demo> --- stop ---
4666 4843 # <demo> auto
4667 4844 print 'This is an automatic block.'
4668 4845 print 'It is executed without asking for confirmation, but printed.'
4669 4846 z = x+y
4670 4847
4671 4848 print 'z=',x
4672 4849
4673 4850 # <demo> --- stop ---
4674 4851 # This is just another normal block.
4675 4852 print 'z is now:', z
4676 4853
4677 4854 print 'bye!'
4678 4855
4679 4856 In order to run a file as a demo, you must first make a Demo object out
4680 4857 of it. If the file is named myscript.py, the following code will make a
4681 4858 demo::
4682 4859
4683 4860 from IPython.demo import Demo
4684 4861
4685 4862 mydemo = Demo('myscript.py')
4686 4863
4687 4864 This creates the mydemo object, whose blocks you run one at a time by
4688 4865 simply calling the object with no arguments. If you have autocall active
4689 4866 in IPython (the default), all you need to do is type::
4690 4867
4691 4868 mydemo
4692 4869
4693 4870 and IPython will call it, executing each block. Demo objects can be
4694 4871 restarted, you can move forward or back skipping blocks, re-execute the
4695 4872 last block, etc. Simply use the Tab key on a demo object to see its
4696 4873 methods, and call '?' on them to see their docstrings for more usage
4697 4874 details. In addition, the demo module itself contains a comprehensive
4698 4875 docstring, which you can access via::
4699 4876
4700 4877 from IPython import demo
4701 4878
4702 4879 demo?
4703 4880
4704 4881 Limitations: It is important to note that these demos are limited to
4705 4882 fairly simple uses. In particular, you can not put division marks in
4706 4883 indented code (loops, if statements, function definitions, etc.)
4707 4884 Supporting something like this would basically require tracking the
4708 4885 internal execution state of the Python interpreter, so only top-level
4709 4886 divisions are allowed. If you want to be able to open an IPython
4710 4887 instance at an arbitrary point in a program, you can use IPython's
4711 4888 embedding facilities, described in detail in Sec. 9
4712 4889
4713 4890
4714 4891 Plotting with matplotlib
4715 4892 ========================
4716 4893
4717 4894 The matplotlib library (http://matplotlib.sourceforge.net
4718 4895 http://matplotlib.sourceforge.net) provides high quality 2D plotting for
4719 4896 Python. Matplotlib can produce plots on screen using a variety of GUI
4720 4897 toolkits, including Tk, GTK and WXPython. It also provides a number of
4721 4898 commands useful for scientific computing, all with a syntax compatible
4722 4899 with that of the popular Matlab program.
4723 4900
4724 4901 IPython accepts the special option -pylab (Sec. 5.2
4725 4902 <node5.html#sec:cmd-line-opts>). This configures it to support
4726 4903 matplotlib, honoring the settings in the .matplotlibrc file. IPython
4727 4904 will detect the user's choice of matplotlib GUI backend, and
4728 4905 automatically select the proper threading model to prevent blocking. It
4729 4906 also sets matplotlib in interactive mode and modifies %run slightly, so
4730 4907 that any matplotlib-based script can be executed using %run and the
4731 4908 final show() command does not block the interactive shell.
4732 4909
4733 4910 The -pylab option must be given first in order for IPython to configure
4734 4911 its threading mode. However, you can still issue other options
4735 4912 afterwards. This allows you to have a matplotlib-based environment
4736 4913 customized with additional modules using the standard IPython profile
4737 4914 mechanism (Sec. 7.3 <node7.html#sec:profiles>): ''ipython -pylab -p
4738 4915 myprofile'' will load the profile defined in ipythonrc-myprofile after
4739 4916 configuring matplotlib.
4740 4917
4918 IPython Extension Api
4919 =====================
4920
4921 IPython api (defined in IPython/ipapi.py) is the public api that
4922 should be used for
4923
4924 * Configuration of user preferences (.ipython/ipy_user_conf.py)
4925 * Creating new profiles (.ipython/ipy_profile_PROFILENAME.py)
4926 * Writing extensions
4927
4928 Note that by using the extension api for configuration (editing
4929 ipy_user_conf.py instead of ipythonrc), you get better validity checks
4930 and get richer functionality - for example, you can import an
4931 extension and call functions in it to configure it for your purposes.
4932
4933 For an example extension (the 'sh' profile), see
4934 IPython/Extensions/ipy_profile_sh.py.
4935
4936 For the last word on what's available, see the source code of
4937 IPython/ipapi.py.
4938
4939
4940 Getting started
4941 ---------------
4942
4943 If you want to define an extension, create a normal python module that
4944 can be imported. The module will access IPython functionality through
4945 the 'ip' object defined below.
4946
4947 If you are creating a new profile (e.g. foobar), name the module as
4948 'ipy_profile_foobar.py' and put it in your ~/.ipython directory. Then,
4949 when you start ipython with the '-p foobar' argument, the module is
4950 automatically imported on ipython startup.
4951
4952 If you are just doing some per-user configuration, you can either
4953
4954 * Put the commands directly into ipy_user_conf.py.
4955
4956 * Create a new module with your customization code and import *that*
4957 module in ipy_user_conf.py. This is preferable to the first approach,
4958 because now you can reuse and distribute your customization code.
4959
4960 Getting a handle to the api
4961 ---------------------------
4962
4963 Put this in the start of your module::
4964
4965 #!python
4966 import IPython.ipapi
4967 ip = IPython.ipapi.get()
4968
4969 The 'ip' object will then be used for accessing IPython
4970 functionality. 'ip' will mean this api object in all the following
4971 code snippets. The same 'ip' that we just acquired is always
4972 accessible in interactive IPython sessions by the name _ip - play with
4973 it like this::
4974
4975 [~\_ipython]|81> a = 10
4976 [~\_ipython]|82> _ip.e
4977 _ip.ev _ip.ex _ip.expose_magic
4978 [~\_ipython]|82> _ip.ev('a+13')
4979 <82> 23
4980
4981 The _ip object is also used in some examples in this document - it can
4982 be substituted by 'ip' in non-interactive use.
4983
4984 Changing options
4985 ----------------
4986
4987 The ip object has 'options' attribute that can be used te get/set
4988 configuration options (just as in the ipythonrc file)::
4989
4990 o = ip.options
4991 o.autocall = 2
4992 o.automagic = 1
4993
4994 Executing statements in IPython namespace with 'ex' and 'ev'
4995 ------------------------------------------------------------
4996
4997 Often, you want to e.g. import some module or define something that
4998 should be visible in IPython namespace. Use ``ip.ev`` to
4999 *evaluate* (calculate the value of) expression and ``ip.ex`` to
5000 '''execute''' a statement::
5001
5002 # path module will be visible to the interactive session
5003 ip.ex("from path import path" )
5004
5005 # define a handy function 'up' that changes the working directory
5006
5007 ip.ex('import os')
5008 ip.ex("def up(): os.chdir('..')")
5009
5010
5011 # _i2 has the input history entry #2, print its value in uppercase.
5012 print ip.ev('_i2.upper()')
5013
5014 Accessing the IPython namespace
5015 -------------------------------
5016
5017 ip.user_ns attribute has a dictionary containing the IPython global
5018 namespace (the namespace visible in the interactive session).
5019
5020 ::
5021
5022 [~\_ipython]|84> tauno = 555
5023 [~\_ipython]|85> _ip.user_ns['tauno']
5024 <85> 555
5025
5026 Defining new magic commands
5027 ---------------------------
5028
5029 The following example defines a new magic command, %impall. What the
5030 command does should be obvious::
5031
5032 def doimp(self, arg):
5033 ip = self.api
5034 ip.ex("import %s; reload(%s); from %s import *" % (
5035 arg,arg,arg)
5036 )
5037
5038 ip.expose_magic('impall', doimp)
5039
5040 Things to observe in this example:
5041
5042 * Define a function that implements the magic command using the
5043 ipapi methods defined in this document
5044 * The first argument of the function is 'self', i.e. the
5045 interpreter object. It shouldn't be used directly. however.
5046 The interpreter object is probably *not* going to remain stable
5047 through IPython versions.
5048 * Access the ipapi through 'self.api' instead of the global 'ip' object.
5049 * All the text following the magic command on the command line is
5050 contained in the second argument
5051 * Expose the magic by ip.expose_magic()
5052
5053
5054 Calling magic functions and system commands
5055 -------------------------------------------
5056
5057 Use ip.magic() to execute a magic function, and ip.system() to execute
5058 a system command::
5059
5060 # go to a bookmark
5061 ip.magic('%cd -b relfiles')
5062
5063 # execute 'ls -F' system command. Interchangeable with os.system('ls'), really.
5064 ip.system('ls -F')
5065
5066 Launching IPython instance from normal python code
5067 --------------------------------------------------
5068
5069 Use ipapi.launch_new_instance() with an argument that specifies the
5070 namespace to use. This can be useful for trivially embedding IPython
5071 into your program. Here's an example of normal python program test.py
5072 ('''without''' an existing IPython session) that launches an IPython
5073 interpreter and regains control when the interpreter is exited::
5074
5075 [ipython]|1> cat test.py
5076 my_ns = dict(
5077 kissa = 15,
5078 koira = 16)
5079 import IPython.ipapi
5080 print "launching IPython instance"
5081 IPython.ipapi.launch_new_instance(my_ns)
5082 print "Exited IPython instance!"
5083 print "New vals:",my_ns['kissa'], my_ns['koira']
5084
5085 And here's what it looks like when run (note how we don't start it
5086 from an ipython session)::
5087
5088 Q:\ipython>python test.py
5089 launching IPython instance
5090 Py 2.5 (r25:51908, Sep 19 2006, 09:52:17) [MSC v.1310 32 bit (Intel)] IPy 0.7.3b3.r1975
5091 [ipython]|1> kissa = 444
5092 [ipython]|2> koira = 555
5093 [ipython]|3> Exit
5094 Exited IPython instance!
5095 New vals: 444 555
5096
5097 Accessing unexposed functionality
5098 ---------------------------------
5099
5100 There are still many features that are not exposed via the ipapi. If
5101 you can't avoid using them, you can use the functionality in
5102 InteractiveShell object (central IPython session class, defined in
5103 iplib.py) through ip.IP.
5104
5105 For example::
5106
5107 [~]|7> _ip.IP.expand_aliases('np','myfile.py')
5108 <7> 'c:/opt/Notepad++/notepad++.exe myfile.py'
5109 [~]|8>
5110
5111 Still, it's preferable that if you encounter such a feature, contact
5112 the IPython team and request that the functionality be exposed in a
5113 future version of IPython. Things not in ipapi are more likely to
5114 change over time.
5115
4741 5116 Reporting bugs
4742 5117 ==============
4743 5118
4744 5119 Automatic crash reports
4745 5120 -----------------------
4746 5121
4747 5122 Ideally, IPython itself shouldn't crash. It will catch exceptions
4748 5123 produced by you, but bugs in its internals will still crash it.
4749 5124
4750 5125 In such a situation, IPython will leave a file named
4751 5126 IPython_crash_report.txt in your IPYTHONDIR directory (that way if
4752 5127 crashes happen several times it won't litter many directories, the
4753 5128 post-mortem file is always located in the same place and new occurrences
4754 5129 just overwrite the previous one). If you can mail this file to the
4755 5130 developers (see sec. 20 <node20.html#sec:credits> for names and
4756 5131 addresses), it will help us a lot in understanding the cause of the
4757 5132 problem and fixing it sooner.
4758 5133
4759 5134
4760 5135 The bug tracker
4761 5136 ---------------
4762 5137
4763 5138 IPython also has an online bug-tracker, located at
4764 5139 http://projects.scipy.org/ipython/ipython/report/1. In addition to
4765 5140 mailing the developers, it would be a good idea to file a bug report
4766 5141 here. This will ensure that the issue is properly followed to
4767 5142 conclusion. To report new bugs you will have to register first.
4768 5143
4769 5144 You can also use this bug tracker to file feature requests.
4770 5145
4771 5146 Brief history
4772 5147 =============
4773 5148
4774 5149
4775 Origins
5150 Origins
5151 -------
4776 5152
4777 5153 The current IPython system grew out of the following three projects:
4778 5154
4779 5155 * [ipython] by Fernando Pérez. I was working on adding
4780 5156 Mathematica-type prompts and a flexible configuration system
4781 5157 (something better than $PYTHONSTARTUP) to the standard Python
4782 5158 interactive interpreter.
4783 5159 * [IPP] by Janko Hauser. Very well organized, great usability. Had
4784 5160 an old help system. IPP was used as the 'container' code into
4785 5161 which I added the functionality from ipython and LazyPython.
4786 5162 * [LazyPython] by Nathan Gray. Simple but very powerful. The quick
4787 5163 syntax (auto parens, auto quotes) and verbose/colored tracebacks
4788 5164 were all taken from here.
4789 5165
4790 5166 When I found out (see sec. 20 <node20.html#figgins>) about IPP and
4791 5167 LazyPython I tried to join all three into a unified system. I thought
4792 5168 this could provide a very nice working environment, both for regular
4793 5169 programming and scientific computing: shell-like features, IDL/Matlab
4794 5170 numerics, Mathematica-type prompt history and great object introspection
4795 5171 and help facilities. I think it worked reasonably well, though it was a
4796 5172 lot more work than I had initially planned.
4797 5173
4798 5174
4799 5175 Current status
4800 5176 --------------
4801 5177
4802 5178 The above listed features work, and quite well for the most part. But
4803 5179 until a major internal restructuring is done (see below), only bug
4804 5180 fixing will be done, no other features will be added (unless very minor
4805 5181 and well localized in the cleaner parts of the code).
4806 5182
4807 5183 IPython consists of some 18000 lines of pure python code, of which
4808 5184 roughly two thirds is reasonably clean. The rest is, messy code which
4809 5185 needs a massive restructuring before any further major work is done.
4810 5186 Even the messy code is fairly well documented though, and most of the
4811 5187 problems in the (non-existent) class design are well pointed to by a
4812 5188 PyChecker run. So the rewriting work isn't that bad, it will just be
4813 5189 time-consuming.
4814 5190
4815 5191
4816 5192 Future
4817 5193 ------
4818 5194
4819 5195 See the separate new_design document for details. Ultimately, I would
4820 5196 like to see IPython become part of the standard Python distribution as a
4821 5197 'big brother with batteries' to the standard Python interactive
4822 5198 interpreter. But that will never happen with the current state of the
4823 5199 code, so all contributions are welcome.
4824 5200
4825 5201 License
4826 5202 =======
4827 5203
4828 5204 IPython is released under the terms of the BSD license, whose general
4829 5205 form can be found at:
4830 5206 http://www.opensource.org/licenses/bsd-license.php. The full text of the
4831 5207 IPython license is reproduced below::
4832 5208
4833 5209 IPython is released under a BSD-type license.
4834 5210
4835 5211 Copyright (c) 2001, 2002, 2003, 2004 Fernando Perez
4836 5212 <fperez@colorado.edu>.
4837 5213
4838 5214 Copyright (c) 2001 Janko Hauser <jhauser@zscout.de> and
4839 5215 Nathaniel Gray <n8gray@caltech.edu>.
4840 5216
4841 5217 All rights reserved.
4842 5218
4843 5219 Redistribution and use in source and binary forms, with or without
4844 5220 modification, are permitted provided that the following conditions
4845 5221 are met:
4846 5222
4847 5223 a. Redistributions of source code must retain the above copyright
4848 5224 notice, this list of conditions and the following disclaimer.
4849 5225
4850 5226 b. Redistributions in binary form must reproduce the above copyright
4851 5227 notice, this list of conditions and the following disclaimer in the
4852 5228 documentation and/or other materials provided with the distribution.
4853 5229
4854 5230 c. Neither the name of the copyright holders nor the names of any
4855 5231 contributors to this software may be used to endorse or promote
4856 5232 products derived from this software without specific prior written
4857 5233 permission.
4858 5234
4859 5235 THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
4860 5236 "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
4861 5237 LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
4862 5238 FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
4863 5239 REGENTS OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
4864 5240 INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
4865 5241 BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
4866 5242 LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
4867 5243 CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
4868 5244 LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
4869 5245 ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
4870 5246 POSSIBILITY OF SUCH DAMAGE.
4871 5247
4872 5248 Individual authors are the holders of the copyright for their code and
4873 5249 are listed in each file.
4874 5250
4875 5251 Some files (DPyGetOpt.py, for example) may be licensed under different
4876 5252 conditions. Ultimately each file indicates clearly the conditions under
4877 5253 which its author/authors have decided to publish the code.
4878 5254
4879 5255 Versions of IPython up to and including 0.6.3 were released under the
4880 5256 GNU Lesser General Public License (LGPL), available at
4881 5257 http://www.gnu.org/copyleft/lesser.html.
4882 5258
4883 5259 Credits
4884 5260 =======
4885 5261
4886 5262 IPython is mainly developed by Fernando Pérez
4887 5263 <Fernando.Perez@colorado.edu>, but the project was born from mixing in
4888 5264 Fernando's code with the IPP project by Janko Hauser
4889 5265 <jhauser-AT-zscout.de> and LazyPython by Nathan Gray
4890 5266 <n8gray-AT-caltech.edu>. For all IPython-related requests, please
4891 5267 contact Fernando.
4892 5268
4893 5269 As of early 2006, the following developers have joined the core team:
4894 5270
4895 5271 * [Robert Kern] <rkern-AT-enthought.com>: co-mentored the 2005
4896 5272 Google Summer of Code project to develop python interactive
4897 5273 notebooks (XML documents) and graphical interface. This project
4898 5274 was awarded to the students Tzanko Matev <tsanko-AT-gmail.com> and
4899 5275 Toni Alatalo <antont-AT-an.org>
4900 5276 * [Brian Granger] <bgranger-AT-scu.edu>: extending IPython to allow
4901 5277 support for interactive parallel computing.
4902 5278 * [Ville Vainio] <vivainio-AT-gmail.com>: Ville is the new
4903 5279 maintainer for the main trunk of IPython after version 0.7.1.
4904 5280
4905 5281 User or development help should be requested via the IPython mailing lists:
4906 5282
4907 5283 *User list:*
4908 5284 http://scipy.net/mailman/listinfo/ipython-user
4909 5285 *Developer's list:*
4910 5286 http://scipy.net/mailman/listinfo/ipython-dev
4911 5287
4912 5288 The IPython project is also very grateful to^7 <footnode.html#foot2913>:
4913 5289
4914 5290 Bill Bumgarner <bbum-AT-friday.com>: for providing the DPyGetOpt module
4915 5291 which gives very powerful and convenient handling of command-line
4916 5292 options (light years ahead of what Python 2.1.1's getopt module does).
4917 5293
4918 5294 Ka-Ping Yee <ping-AT-lfw.org>: for providing the Itpl module for
4919 5295 convenient and powerful string interpolation with a much nicer syntax
4920 5296 than formatting through the '%' operator.
4921 5297
4922 5298 Arnd Baecker <baecker-AT-physik.tu-dresden.de>: for his many very useful
4923 5299 suggestions and comments, and lots of help with testing and
4924 5300 documentation checking. Many of IPython's newer features are a result of
4925 5301 discussions with him (bugs are still my fault, not his).
4926 5302
4927 5303 Obviously Guido van Rossum and the whole Python development team, that
4928 5304 goes without saying.
4929 5305
4930 5306 IPython's website is generously hosted at http://ipython.scipy.orgby
4931 5307 Enthought (http://www.enthought.com). I am very grateful to them and all
4932 5308 of the SciPy team for their contribution.
4933 5309
4934 5310 Fernando would also like to thank Stephen Figgins <fig-AT-monitor.net>,
4935 5311 an O'Reilly Python editor. His Oct/11/2001 article about IPP and
4936 5312 LazyPython, was what got this project started. You can read it at:
4937 5313 http://www.onlamp.com/pub/a/python/2001/10/11/pythonnews.html.
4938 5314
4939 5315 And last but not least, all the kind IPython users who have emailed new
4940 5316 code, bug reports, fixes, comments and ideas. A brief list follows,
4941 5317 please let me know if I have ommitted your name by accident:
4942 5318
4943 5319 * [Jack Moffit] <jack-AT-xiph.org> Bug fixes, including the infamous
4944 5320 color problem. This bug alone caused many lost hours and
4945 5321 frustration, many thanks to him for the fix. I've always been a
4946 5322 fan of Ogg & friends, now I have one more reason to like these folks.
4947 5323 Jack is also contributing with Debian packaging and many other
4948 5324 things.
4949 5325 * [Alexander Schmolck] <a.schmolck-AT-gmx.net> Emacs work, bug
4950 5326 reports, bug fixes, ideas, lots more. The ipython.el mode for
4951 5327 (X)Emacs is Alex's code, providing full support for IPython under
4952 5328 (X)Emacs.
4953 5329 * [Andrea Riciputi] <andrea.riciputi-AT-libero.it> Mac OSX
4954 5330 information, Fink package management.
4955 5331 * [Gary Bishop] <gb-AT-cs.unc.edu> Bug reports, and patches to work
4956 5332 around the exception handling idiosyncracies of WxPython. Readline
4957 5333 and color support for Windows.
4958 5334 * [Jeffrey Collins] <Jeff.Collins-AT-vexcel.com> Bug reports. Much
4959 5335 improved readline support, including fixes for Python 2.3.
4960 5336 * [Dryice Liu] <dryice-AT-liu.com.cn> FreeBSD port.
4961 5337 * [Mike Heeter] <korora-AT-SDF.LONESTAR.ORG>
4962 5338 * [Christopher Hart] <hart-AT-caltech.edu> PDB integration.
4963 5339 * [Milan Zamazal] <pdm-AT-zamazal.org> Emacs info.
4964 5340 * [Philip Hisley] <compsys-AT-starpower.net>
4965 5341 * [Holger Krekel] <pyth-AT-devel.trillke.net> Tab completion, lots
4966 5342 more.
4967 5343 * [Robin Siebler] <robinsiebler-AT-starband.net>
4968 5344 * [Ralf Ahlbrink] <ralf_ahlbrink-AT-web.de>
4969 5345 * [Thorsten Kampe] <thorsten-AT-thorstenkampe.de>
4970 5346 * [Fredrik Kant] <fredrik.kant-AT-front.com> Windows setup.
4971 5347 * [Syver Enstad] <syver-en-AT-online.no> Windows setup.
4972 5348 * [Richard] <rxe-AT-renre-europe.com> Global embedding.
4973 5349 * [Hayden Callow] <h.callow-AT-elec.canterbury.ac.nz> Gnuplot.py 1.6
4974 5350 compatibility.
4975 5351 * [Leonardo Santagada] <retype-AT-terra.com.br> Fixes for Windows
4976 5352 installation.
4977 5353 * [Christopher Armstrong] <radix-AT-twistedmatrix.com> Bugfixes.
4978 5354 * [Francois Pinard] <pinard-AT-iro.umontreal.ca> Code and
4979 5355 documentation fixes.
4980 5356 * [Cory Dodt] <cdodt-AT-fcoe.k12.ca.us> Bug reports and Windows
4981 5357 ideas. Patches for Windows installer.
4982 5358 * [Olivier Aubert] <oaubert-AT-bat710.univ-lyon1.fr> New magics.
4983 5359 * [King C. Shu] <kingshu-AT-myrealbox.com> Autoindent patch.
4984 5360 * [Chris Drexler] <chris-AT-ac-drexler.de> Readline packages for
4985 5361 Win32/CygWin.
4986 5362 * [Gustavo Cordova Avila] <gcordova-AT-sismex.com> EvalDict code for
4987 5363 nice, lightweight string interpolation.
4988 5364 * [Kasper Souren] <Kasper.Souren-AT-ircam.fr> Bug reports, ideas.
4989 5365 * [Gever Tulley] <gever-AT-helium.com> Code contributions.
4990 5366 * [Ralf Schmitt] <ralf-AT-brainbot.com> Bug reports & fixes.
4991 5367 * [Oliver Sander] <osander-AT-gmx.de> Bug reports.
4992 5368 * [Rod Holland] <rhh-AT-structurelabs.com> Bug reports and fixes to
4993 5369 logging module.
4994 5370 * [Daniel 'Dang' Griffith] <pythondev-dang-AT-lazytwinacres.net>
4995 5371 Fixes, enhancement suggestions for system shell use.
4996 5372 * [Viktor Ransmayr] <viktor.ransmayr-AT-t-online.de> Tests and
4997 5373 reports on Windows installation issues. Contributed a true Windows
4998 5374 binary installer.
4999 5375 * [Mike Salib] <msalib-AT-mit.edu> Help fixing a subtle bug related
5000 5376 to traceback printing.
5001 5377 * [W.J. van der Laan] <gnufnork-AT-hetdigitalegat.nl> Bash-like
5002 5378 prompt specials.
5003 5379 * [Antoon Pardon] <Antoon.Pardon-AT-rece.vub.ac.be> Critical fix for
5004 5380 the multithreaded IPython.
5005 5381 * [John Hunter] <jdhunter-AT-nitace.bsd.uchicago.edu> Matplotlib
5006 5382 author, helped with all the development of support for matplotlib
5007 5383 in IPyhton, including making necessary changes to matplotlib itself.
5008 5384 * [Matthew Arnison] <maffew-AT-cat.org.au> Bug reports, '%run -d' idea.
5009 5385 * [Prabhu Ramachandran] <prabhu_r-AT-users.sourceforge.net> Help
5010 5386 with (X)Emacs support, threading patches, ideas...
5011 5387 * [Norbert Tretkowski] <tretkowski-AT-inittab.de> help with Debian
5012 5388 packaging and distribution.
5013 5389 * [George Sakkis] <gsakkis-AT-eden.rutgers.edu> New matcher for
5014 5390 tab-completing named arguments of user-defined functions.
5015 5391 * [Jörgen Stenarson] <jorgen.stenarson-AT-bostream.nu> Wildcard
5016 5392 support implementation for searching namespaces.
5017 5393 * [Vivian De Smedt] <vivian-AT-vdesmedt.com> Debugger enhancements,
5018 5394 so that when pdb is activated from within IPython, coloring, tab
5019 5395 completion and other features continue to work seamlessly.
5020 5396 * [Scott Tsai] <scottt958-AT-yahoo.com.tw> Support for automatic
5021 5397 editor invocation on syntax errors (see
5022 5398 http://www.scipy.net/roundup/ipython/issue36).
5023 5399 * [Alexander Belchenko] <bialix-AT-ukr.net> Improvements for win32
5024 5400 paging system.
5025 5401 * [Will Maier] <willmaier-AT-ml1.net> Official OpenBSD port.
5026 5402
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