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/ docs / examples / core / leo_bridge_demo.leo
Ville M. Vainio
add leo_bridge_demo example, add @cl (data class) support (e.g. @cl csvdata, @cl tmpfile, @cl rfile)
r994 <?xml version="1.0" encoding="utf-8"?>
<?xml-stylesheet ekr_test?>
<leo_file>
<leo_header file_format="2" tnodes="0" max_tnode_index="0" clone_windows="0"/>
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ipy_leo: doc improvements
r1010 <globals body_outline_ratio="0.307814992026">
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r1115 <global_window_position top="257" left="131" height="627" width="1280"/>
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r994 <global_log_window_position top="0" left="0" height="0" width="0"/>
</globals>
<preferences/>
<find_panel_settings/>
<vnodes>
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r1010 <v t="vivainio.20080222193236" a="E"><vh>Documentation</vh>
Ville M. Vainio
ipy_leo: minor doc adjustment
r1013 <v t="vivainio.20080223121915" tnodeList="vivainio.20080223121915,vivainio.20080222193236.1,vivainio.20080223133858,vivainio.20080223133922,vivainio.20080223133947,vivainio.20080223134018,vivainio.20080223134100,vivainio.20080223134118,vivainio.20080223134433,vivainio.20080223142207,vivainio.20080223134136"><vh>@nosent ILeo_doc.txt</vh>
<v t="vivainio.20080222193236.1"><vh>Documentation</vh>
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r1010 <v t="vivainio.20080223133858"><vh>Introduction</vh></v>
<v t="vivainio.20080223133922"><vh>Installation</vh></v>
<v t="vivainio.20080223133947"><vh>Accessing IPython from Leo</vh></v>
Ville M. Vainio
ipy_leo: minor doc adjustment
r1013 <v t="vivainio.20080223134018"><vh>Accessing Leo nodes from IPython</vh></v>
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ipy_leo: doc improvements
r1010 <v t="vivainio.20080223134100"><vh>Cl definitions</vh></v>
<v t="vivainio.20080223134118"><vh>Special node types</vh></v>
<v t="vivainio.20080223134433"><vh>Custom push</vh></v>
<v t="vivainio.20080223142207" a="E"><vh>Code snippets</vh></v>
<v t="vivainio.20080223134136"><vh>Acknowledgements and history</vh></v>
</v>
</v>
</v>
Ville M. Vainio
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r994 <v t="vivainio.20080218184525"><vh>@chapters</vh></v>
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ileo: have pylab use as example in leo_bridge_demo.leo
r1074 <v t="vivainio.20080223133721" a="E"><vh>@settings</vh>
<v t="vivainio.20080316092617"><vh>@@string ipython_argv = ipython -pylab</vh></v>
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r1007 <v t="vivainio.20080223133721.1"><vh>@enabled-plugins</vh></v>
</v>
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ipy_leo: minor doc adjustment
r1013 <v t="vivainio.20080218184540"><vh>@ipy-startup</vh>
Ville M. Vainio
add quick intro to leo_bridge_demo
r1005 <v t="vivainio.20080218184613.1"><vh>b</vh></v>
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ipy_leo: doc improvements
r1010 <v t="vivainio.20080218200031"><vh>Some classes P</vh>
Ville M. Vainio
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r994 <v t="vivainio.20080218190816"><vh>File-like access</vh></v>
Ville M. Vainio
ipy_leo: '@ipy foo' like nodes can now contain @cl directive
r995 <v t="vivainio.20080218200106"><vh>csv data</vh></v>
Ville M. Vainio
ipy_leo: @cl transform takes node ref in addition to body text
r998 <v t="vivainio.20080219225120"><vh>String list</vh></v>
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ipy_leo: @ipy-startup children are run in sequence, not ipy_startup itself
r999 <v t="vivainio.20080219230342"><vh>slist to leo</vh></v>
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r994 </v>
</v>
Ville M. Vainio
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r1115 <v t="vivainio.20080218195413" a="E"><vh>Class tests</vh>
Ville M. Vainio
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r994 <v t="vivainio.20080218200509"><vh>csvr</vh></v>
<v t="vivainio.20080218191007"><vh>tempfile</vh></v>
<v t="vivainio.20080218195413.1"><vh>rfile</vh></v>
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r998 <v t="vivainio.20080219225804"><vh>strlist</vh></v>
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r994 </v>
Ville M. Vainio
ipapi, ileo: fix _ip.runlines() cleanup routine for better handling of secondary blocks (else etc)
r1115 <v t="vivainio.20080222201226" a="V"><vh>IPython script push tests</vh></v>
Ville M. Vainio
ipy_leo: minor doc adjustment
r1013 <v t="vivainio.20080218201219" a="E"><vh>Direct variables</vh>
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r1005 <v t="vivainio.20080218201219.2"><vh>bar</vh></v>
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r995 </v>
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r1075 <v t="vivainio.20080316144536" a="E"><vh>pylab tests</vh>
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r1115 <v t="vivainio.20080316145539.2"><vh>Generate testarr</vh></v>
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r1074 <v t="vivainio.20080316085925"><vh>testarr</vh></v>
<v t="vivainio.20080316085950"><vh>Call plotter on testarr</vh></v>
</v>
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r1010 <v t="vivainio.20080222202211"><vh>test stuff</vh></v>
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r1074 <v t="vivainio.20080223142403"><vh>@ipy-results</vh>
Ville M. Vainio
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r1010 <v t="vivainio.20080223142403.1"><vh>foo</vh></v>
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r1007 </v>
Ville M. Vainio
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r1071 <v t="vivainio.20080222202211.1" a="E"><vh>spam</vh></v>
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r994 </vnodes>
<tnodes>
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r995 <t tx="vivainio.20080218184525">?</t>
Ville M. Vainio
ipy_leo: @ipy-startup children are run in sequence, not ipy_startup itself
r999 <t tx="vivainio.20080218184540">?Direct children of this node will be pushed at ipython bridge startup
Ville M. Vainio
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r994
Ville M. Vainio
ipy_leo: @ipy-startup children are run in sequence, not ipy_startup itself
r999 This node itself will *not* be pushed</t>
Ville M. Vainio
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r994 <t tx="vivainio.20080218184613.1">print "world"</t>
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r998 <t tx="vivainio.20080218190816">def rfile(body,n):
Ville M. Vainio
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r994 """ @cl rfile
produces a StringIO (file like obj of the rest of the body) """
import StringIO
return StringIO.StringIO(body)
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r998 def tmpfile(body,n):
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r994 """ @cl tmpfile
Produces a temporary file, with node body as contents
"""
import tempfile
h, fname = tempfile.mkstemp()
f = open(fname,'w')
f.write(body)
f.close()
return fname
</t>
<t tx="vivainio.20080218191007">@cl tmpfile
Hello</t>
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deprecated @ipy header prefix, use @cl alone as first body line instead...
r996 <t tx="vivainio.20080218195413">?</t>
Ville M. Vainio
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r994 <t tx="vivainio.20080218195413.1">@cl rfile
These
lines
should
be
readable </t>
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r999 <t tx="vivainio.20080218200031">@others</t>
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r998 <t tx="vivainio.20080218200106">def csvdata(body,n):
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r994 import csv
d = csv.Sniffer().sniff(body)
reader = csv.reader(body.splitlines(), dialect = d)
return reader</t>
<t tx="vivainio.20080218200509">@cl csvdata
a,b,b
1,2,2</t>
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r995 <t tx="vivainio.20080218201219"></t>
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r998 <t tx="vivainio.20080218201219.2">@cl
"hello world"</t>
<t tx="vivainio.20080219225120">import IPython.genutils
def slist(body,n):
return IPython.genutils.SList(body.splitlines())
</t>
<t tx="vivainio.20080219225804">@cl slist
hello
world
on
many
lines
</t>
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r999 <t tx="vivainio.20080219230342">import ipy_leo
@ipy_leo.format_for_leo.when_type(IPython.genutils.SList)
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r998 def format_slist(obj):
return "@cl slist\n" + obj.n
</t>
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r1010 <t tx="vivainio.20080222193236">?</t>
Ville M. Vainio
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r1005 <t tx="vivainio.20080222193236.1">@wrap
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ipy_leo: improved ipy_leo docs
r1007 @nocolor</t>
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r1115 <t tx="vivainio.20080222201226"># test ipython script 'cleanup' with complex blocks
1+2
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r1007 print "hello"
3+4
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r1005
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r1007 def f(x):
return x.upper()
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r1071
if 0:
print "foo"
else:
print "bar"
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ileo: have pylab use as example in leo_bridge_demo.leo
r1074
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r1115 def g():
pass
g()
if 1:
if 1:
print "hello"
print "world"
if 1:
print "hello"
print "word"
else:
print "foo"
print "bar"
print "baz"
try:
raise Exception
except:
print "exc ok"</t>
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ipy_leo: improved ipy_leo docs
r1007 <t tx="vivainio.20080222202211"></t>
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ipy_leo: doc improvements
r1010 <t tx="vivainio.20080222202211.1" ipython="7d71005506636f6f7264737101284b0c4bde747102732e">@cl rfile
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r1007 hello
world
and whatever</t>
<t tx="vivainio.20080223121915">@others
</t>
<t tx="vivainio.20080223133721"></t>
<t tx="vivainio.20080223133721.1">ipython.py</t>
<t tx="vivainio.20080223133858">
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r1005 Introduction
============
The purpose of ILeo, or leo-ipython bridge, is being a two-way communication
channel between Leo and IPython. The level of integration is much deeper than
conventional integration in IDEs; most notably, you are able to store *data* in
Leo nodes, in addition to mere program code. The possibilities of this are
endless, and this degree of integration has not been seen previously in the python
world.
IPython users are accustomed to using things like %edit to produce non-trivial
functions/classes (i.e. something that they don't want to enter directly on the
interactive prompt, but creating a proper script/module involves too much
overhead). In ILeo, this task consists just going to the Leo window, creating a node
and writing the code there, and pressing alt+I (push-to-ipython).
Obviously, you can save the Leo document as usual - this is a great advantage
of ILeo over using %edit, you can save your experimental scripts all at one
time, without having to organize them into script/module files (before you
really want to, of course!)
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r1007 </t>
<t tx="vivainio.20080223133922">
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r1005 Installation
============
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r1007 You need at least Leo 4.4.7, and the development version of IPython (ILeo
will be incorporated to IPython 0.8.3).
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r1005
You can get IPython from Launchpad by installing bzr and doing
bzr branch lp:ipython
and running "setup.py install".
You need to enable the 'ipython.py' plugin in Leo:
- Help -&gt; Open LeoSettings.leo
- Edit @settings--&gt;Plugins--&gt;@enabled-plugins, add/uncomment 'ipython.py'
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r1010 - Alternatively, you can add @settings--&gt;@enabled-plugins with body ipython.py to your leo document.
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r1005 - Restart Leo. Be sure that you have the console window open (start leo.py from console, or double-click leo.py on windows)
- Press alt+5 OR alt-x start-ipython to launch IPython in the console that
started leo. You can start entering IPython commands normally, and Leo will keep
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r1007 running at the same time.
</t>
<t tx="vivainio.20080223133947">
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r1005 Accessing IPython from Leo
==========================
IPython code
------------
Just enter IPython commands on a Leo node and press alt-I to execute
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r1010 push-to-ipython in order to execute the script in IPython. 'commands' is
interpreted loosely here - you can enter function and class definitions, in
addition to the things you would usually enter at IPython prompt - calculations,
system commands etc.
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r1005
Everything that would be legal to enter on IPython prompt is legal to execute
from ILeo.
Results will be shows in Leo log window for convenience, in addition to the console.
Suppose that a node had the following contents:
{{{
1+2
print "hello"
3+4
def f(x):
return x.upper()
f('hello world')
}}}
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ipy_leo: doc improvements
r1010 If you press alt+I on that node, you will see the following in Leo log window (IPython tab):
Ville M. Vainio
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r1007
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r1005 {{{
In: 1+2
&lt;2&gt; 3
In: 3+4
&lt;4&gt; 7
In: f('hello world')
&lt;6&gt; 'HELLO WORLD'
}}}
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ipy_leo: doc improvements
r1010 (numbers like &lt;6&gt; mean IPython output history indices; the actual object can be
referenced with _6 as usual in IPython).
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r1005
Plain Python code
-----------------
If the headline of the node ends with capital P, alt-I will not run the code
through IPython translation mechanism but use the direct python 'exec' statement
(in IPython user namespace) to execute the code. It wont be shown in IPython
history, and sometimes it is safer (and more efficient) to execute things as
plain Python statements. Large class definitions are good candidates for P
nodes.
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ipy_leo: improved ipy_leo docs
r1007 </t>
<t tx="vivainio.20080223134018">
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r1005 Accessing Leo nodes from IPython
================================
The real fun starts when you start entering text to leo nodes, and are using
that as data (input/output) for your IPython work.
Accessing Leo nodes happens through the variable 'wb' (short for "WorkBook")
that exist in the IPython user namespace. Nodes that are directly accessible are
the ones that have simple names which could also be Python variable names;
'foo_1' will be accessible directly from IPython, whereas 'my scripts' will not.
If you want to access a node with arbitrary headline, add a child node '@a foo'
(@a stands for 'anchor'). Then, the parent of '@a foo' is accessible through
'wb.foo'.
You can see what nodes are accessible be entering (in IPython) wb.&lt;TAB&gt;. Example:
[C:leo/src]|12&gt; wb.
wb.b wb.tempfile wb.rfile wb.NewHeadline
wb.bar wb.Docs wb.strlist wb.csvr
Ville M. Vainio
ipy_leo: doc improvements
r1010 [C:leo/src]|12&gt; wb.tempfile
&lt;12&gt; &lt;ipy_leo.LeoNode object at 0x044B6D90&gt;
So here, we meet the 'LeoNode' class that is your key to manipulating Leo
content from IPython!
LeoNode
-------
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r1005
Suppose that we had a node with headline 'spam' and body:
['12',2222+32]
we can access it from IPython (or from scripts entered into other Leo nodes!) by doing:
Ville M. Vainio
ipy_leo: improved ipy_leo docs
r1007
Ville M. Vainio
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r1005 C:leo/src]|19&gt; wb.spam.v
&lt;19&gt; ['12', 2254]
'v' attribute stands for 'value', which means the node contents will be run
through 'eval' and everything you would be able to enter into IPython prompt
will be converted to objects. This mechanism can be extended far beyond direct
evaluation (see '@cl definitions').
'v' attribute also has a setter, i.e. you can do:
wb.spam.v = "mystring"
Which will result in the node 'spam' having the following text:
'mystring'
What assignment to 'v' does can be configured through generic functions
Ville M. Vainio
ipy_leo: doc improvements
r1010 ('simplegeneric' module, will be explained later).
Besides v, you can set the body text directly through
wb.spam.b = "some\nstring",
headline by
wb.spam.h = 'new_headline'
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r1005
Ville M. Vainio
ipy_leo: doc improvements
r1010 (obviously you must access the node through wb.new_headline from that point
onwards), and access the contents as string list (IPython SList) through
'wb.spam.l'.
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r1005
If you do 'wb.foo.v = 12' when node named 'foo' does not exist, the node titled
'foo' will be automatically created and assigned body 12.
Ville M. Vainio
ipy_leo: doc improvements
r1010
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ipy_leo: doc
r1011 LeoNode also supports go() that focuses the node in the Leo window, and ipush()
that simulates pressing alt+I on the node.
Ville M. Vainio
ipy_leo: doc improvements
r1010
You can access unknownAttributes by .uA property dictionary. Unknown attributes
Ville M. Vainio
ipy_leo: doc
r1011 allow you to store arbitrary (pickleable) python objects in the Leo nodes; the
attributes are stored when you save the .leo document, and recreated when you
open the document again. The attributes are not visible anywhere, but can be
used for domain-specific metatada. Example:
Ville M. Vainio
ipy_leo: doc improvements
r1010
[C:leo/src]|12&gt; wb.spam.uA['coords'] = (12,222)
[C:leo/src]|13&gt; wb.spam.uA
&lt;13&gt; {'coords': (12, 222)}
Accessing children with iteration and dict notation
---------------------------------------------------
Sometimes, you may want to treat a node as a 'database', where the nodes
children represent elements in the database. You can create a new child node for
node 'spam', with headline 'foo bar' like this:
wb.spam['foo bar'] = "Hello"
And assign a new value for it by doing
wb.spam['foo bar'].v = "Hello again"
Note how you can't use .v when you first create the node - i.e. the node needs
to be initialized by simple assignment, that will be interpreted as assignment
to '.v'. This is a conscious design choice.
If you try to do wb.spam['bar'] = 'Hello', ILeo will assign '@k bar' as the
headline for the child instead, because 'bar' is a legal python name (and as
such would be incorporated in the workbook namespace). This is done to avoid
crowding the workbook namespace with extraneous items. The item will still be
accessible as wb.spam['bar']
LeoNodes are iterable, so to see the headlines of all the children of 'spam' do:
for n in wb.spam:
print n.h
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ipy_leo: improved ipy_leo docs
r1007 </t>
<t tx="vivainio.20080223134100">
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r1005 @cl definitions
===============
If the first line in the body text is of the form '@cl sometext', IPython will
Ville M. Vainio
ipy_leo: doc improvements
r1010 evaluate 'sometext' and call the result with the rest of the body when you do
'wb.foo.v'. An example is in place here. Suppose that we have defined a class (I
use the term class in a non-python sense here)
Ville M. Vainio
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r1005
{{{
Ville M. Vainio
ipy_leo: doc improvements
r1010 def rfile(body,node):
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add quick intro to leo_bridge_demo
r1005 """ @cl rfile
produces a StringIO (file like obj) of the rest of the body """
import StringIO
return StringIO.StringIO(body)
}}}
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r1010 (note that node is ignored here - but it could be used to access headline,
children etc.),
Now, let's say you have node 'spam' with text
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{{{
@cl rfile
hello
world
and whatever
}}}
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r1010 Now, in IPython, we can do this:
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{{{
[C:leo/src]|22&gt; f = wb.spam.v
[C:leo/src]|23&gt; f
&lt;23&gt; &lt;StringIO.StringIO instance at 0x04E7E490&gt;
[C:leo/src]|24&gt; f.readline()
&lt;24&gt; u'hello\n'
[C:leo/src]|25&gt; f.readline()
&lt;25&gt; u'world\n'
[C:leo/src]|26&gt; f.readline()
&lt;26&gt; u'and whatever'
[C:leo/src]|27&gt; f.readline()
&lt;27&gt; u''
}}}
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r1010 You should declare new @cl types to make ILeo as convenient your problem domain
as possible. For example, a "@cl etree" could return the elementtree object for
xml content.
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r1007 </t>
<t tx="vivainio.20080223134118">
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r1005 Special node types
==================
@ipy-startup
------------
If this node exist, the *direct children* of this will be pushed to IPython when
ILeo is started (you press alt+5). Use it to push your own @cl definitions etc.
The contents of of the node itself will be ignored.
@ipy-results
------------
When you create a new node (wb.foo.v = 'stuff'), the node foo will be created as
a child of this node. If @ipy-results does not exist, the new node will be created after the currently selected node.
@a nodes
--------
You can attach these as children of existing nodes to provide a way to access
nodes with arbitrary headlines, or to provide aliases to other nodes. If
multiple @a nodes are attached as children of a node, all the names can be used
to access the same object.
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r1007 </t>
<t tx="vivainio.20080223134136">
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r1005 Acknowledgements &amp; History
==========================
This idea got started when I (Ville) saw this post by Edward Ream (the author of
Leo) on IPython developer mailing list:
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r1005 http://lists.ipython.scipy.org/pipermail/ipython-dev/2008-January/003551.html
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r1005 I was using FreeMind as mind mapping software, and so I had an immediate use
case for Leo (which, incidentally, is superior to FreeMind as mind mapper). The
wheels started rolling, I got obsessed with the power of this concept
(everything clicked together), and Edwards excitement paralleled mine.
Everything was mind-bogglingly easy/trivial, something that is typical of all
revolutionary technologies (think Python here).
The discussion that "built" ILeo is here:
http://sourceforge.net/forum/forum.php?thread_id=1911662&amp;forum_id=10226
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r1007 ?</t>
<t tx="vivainio.20080223134433">
Declaring custom push-to-ipython handlers
=========================================
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r1007 Sometimes, you might want to configure what alt+I on a node does. You can do
that by creating your own push function and expose it using
ipy_leo.expose_ileo_push(f, priority). The function should check whether the
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r1010 node should by handled by the function and raise IPython.ipapi.TryNext if it
will not do the handling, giving the next function in the chain a chance to see
whether it should handle the push.
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r1010 This example would print an uppercase version of node body if the node headline ends
with U (yes, this is completely useless!):
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r1010 {{{
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r1007 def push_upcase(node):
if not node.h.endswith('U'):
raise TryNext
print node.b.upper()
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r1010 ipy_leo.expose_ileo_push(push_upcase, 12)
}}}
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(the priority should be between 0-100 - typically, you don't need to care about
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r1010 it and can usually omit the argument altogether)
</t>
<t tx="vivainio.20080223142207">
Example code snippets
=====================
Get list of all headlines of all the nodes in leo:
[node.h for node in wb]
Create node with headline 'baz', empty body:
wb.baz
Create 10 child nodes for baz, where i is headline and 'Hello ' + i is body:
for i in range(10):
wb.baz[i] = 'Hello %d' % i
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r1007 </t>
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r1010 <t tx="vivainio.20080223142403"></t>
<t tx="vivainio.20080223142403.1">12</t>
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r1075 <t tx="vivainio.20080316085925">array([[ 0, 1, 2],
[ 3, 4, 5],
[ 6, 7, 8],
[ 9, 10, 11]])</t>
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r1074 <t tx="vivainio.20080316085950"># press alt+i here to plot testarr
plot(wb.testarr.v)</t>
<t tx="vivainio.20080316092617"></t>
<t tx="vivainio.20080316144536">Quickstart:
easy_install numpy
easy_install matplotlib
Make sure you have '@string ipython-argv = ipython -pylab' in @settings. We currently recommend using TkAgg as the backend (it's also the default)</t>
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r1075 <t tx="vivainio.20080316145539.2">#press alt+i here to generate an array for plotter
wb.testarr.v = arange(12).reshape(4,3)</t>
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r994 </tnodes>
</leo_file>