##// END OF EJS Templates
Fix a bug in renaming notebook...
Fix a bug in renaming notebook There was a bug in NotebookManager.save_notebook_object. Here is how to reproduce: 0. Make sure you don't have Untitled0. 1. Open new notebook Untitled0. 2. Rename it to something else. 3. Copy Untitled0.ipynb to the notebook dir from somewhere. (Do not use notebook UI.) 4. New copied Untitled0 cannot be opened. The renamed notebook is opened when tried. Indeed, accessing to http://localhost:XXXX/notebooks shows duplicated notebook_id. The problem was that NotebookManager.rev_mapping keeps old notebook name after renaming.

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test_inputsplitter.py
798 lines | 27.2 KiB | text/x-python | PythonLexer
/ IPython / core / tests / test_inputsplitter.py
# -*- coding: utf-8 -*-
"""Tests for the inputsplitter module.
Authors
-------
* Fernando Perez
* Robert Kern
"""
#-----------------------------------------------------------------------------
# Copyright (C) 2010-2011 The IPython Development Team
#
# Distributed under the terms of the BSD License. The full license is in
# the file COPYING, distributed as part of this software.
#-----------------------------------------------------------------------------
#-----------------------------------------------------------------------------
# Imports
#-----------------------------------------------------------------------------
# stdlib
import unittest
import sys
# Third party
import nose.tools as nt
# Our own
from IPython.core import inputsplitter as isp
from IPython.testing import tools as tt
from IPython.utils import py3compat
#-----------------------------------------------------------------------------
# Semi-complete examples (also used as tests)
#-----------------------------------------------------------------------------
# Note: at the bottom, there's a slightly more complete version of this that
# can be useful during development of code here.
def mini_interactive_loop(input_func):
"""Minimal example of the logic of an interactive interpreter loop.
This serves as an example, and it is used by the test system with a fake
raw_input that simulates interactive input."""
from IPython.core.inputsplitter import InputSplitter
isp = InputSplitter()
# In practice, this input loop would be wrapped in an outside loop to read
# input indefinitely, until some exit/quit command was issued. Here we
# only illustrate the basic inner loop.
while isp.push_accepts_more():
indent = ' '*isp.indent_spaces
prompt = '>>> ' + indent
line = indent + input_func(prompt)
isp.push(line)
# Here we just return input so we can use it in a test suite, but a real
# interpreter would instead send it for execution somewhere.
src = isp.source_reset()
#print 'Input source was:\n', src # dbg
return src
#-----------------------------------------------------------------------------
# Test utilities, just for local use
#-----------------------------------------------------------------------------
def assemble(block):
"""Assemble a block into multi-line sub-blocks."""
return ['\n'.join(sub_block)+'\n' for sub_block in block]
def pseudo_input(lines):
"""Return a function that acts like raw_input but feeds the input list."""
ilines = iter(lines)
def raw_in(prompt):
try:
return next(ilines)
except StopIteration:
return ''
return raw_in
#-----------------------------------------------------------------------------
# Tests
#-----------------------------------------------------------------------------
def test_spaces():
tests = [('', 0),
(' ', 1),
('\n', 0),
(' \n', 1),
('x', 0),
(' x', 1),
(' x',2),
(' x',4),
# Note: tabs are counted as a single whitespace!
('\tx', 1),
('\t x', 2),
]
tt.check_pairs(isp.num_ini_spaces, tests)
def test_remove_comments():
tests = [('text', 'text'),
('text # comment', 'text '),
('text # comment\n', 'text \n'),
('text # comment \n', 'text \n'),
('line # c \nline\n','line \nline\n'),
('line # c \nline#c2 \nline\nline #c\n\n',
'line \nline\nline\nline \n\n'),
]
tt.check_pairs(isp.remove_comments, tests)
def test_has_comment():
tests = [('text', False),
('text #comment', True),
('text #comment\n', True),
('#comment', True),
('#comment\n', True),
('a = "#string"', False),
('a = "#string" # comment', True),
('a #comment not "string"', True),
]
tt.check_pairs(isp.has_comment, tests)
def test_get_input_encoding():
encoding = isp.get_input_encoding()
nt.assert_true(isinstance(encoding, basestring))
# simple-minded check that at least encoding a simple string works with the
# encoding we got.
nt.assert_equal(u'test'.encode(encoding), b'test')
class NoInputEncodingTestCase(unittest.TestCase):
def setUp(self):
self.old_stdin = sys.stdin
class X: pass
fake_stdin = X()
sys.stdin = fake_stdin
def test(self):
# Verify that if sys.stdin has no 'encoding' attribute we do the right
# thing
enc = isp.get_input_encoding()
self.assertEqual(enc, 'ascii')
def tearDown(self):
sys.stdin = self.old_stdin
class InputSplitterTestCase(unittest.TestCase):
def setUp(self):
self.isp = isp.InputSplitter()
def test_reset(self):
isp = self.isp
isp.push('x=1')
isp.reset()
self.assertEqual(isp._buffer, [])
self.assertEqual(isp.indent_spaces, 0)
self.assertEqual(isp.source, '')
self.assertEqual(isp.code, None)
self.assertEqual(isp._is_complete, False)
def test_source(self):
self.isp._store('1')
self.isp._store('2')
self.assertEqual(self.isp.source, '1\n2\n')
self.assertTrue(len(self.isp._buffer)>0)
self.assertEqual(self.isp.source_reset(), '1\n2\n')
self.assertEqual(self.isp._buffer, [])
self.assertEqual(self.isp.source, '')
def test_indent(self):
isp = self.isp # shorthand
isp.push('x=1')
self.assertEqual(isp.indent_spaces, 0)
isp.push('if 1:\n x=1')
self.assertEqual(isp.indent_spaces, 4)
isp.push('y=2\n')
self.assertEqual(isp.indent_spaces, 0)
def test_indent2(self):
# In cell mode, inputs must be fed in whole blocks, so skip this test
if self.isp.input_mode == 'cell': return
isp = self.isp
isp.push('if 1:')
self.assertEqual(isp.indent_spaces, 4)
isp.push(' x=1')
self.assertEqual(isp.indent_spaces, 4)
# Blank lines shouldn't change the indent level
isp.push(' '*2)
self.assertEqual(isp.indent_spaces, 4)
def test_indent3(self):
# In cell mode, inputs must be fed in whole blocks, so skip this test
if self.isp.input_mode == 'cell': return
isp = self.isp
# When a multiline statement contains parens or multiline strings, we
# shouldn't get confused.
isp.push("if 1:")
isp.push(" x = (1+\n 2)")
self.assertEqual(isp.indent_spaces, 4)
def test_indent4(self):
# In cell mode, inputs must be fed in whole blocks, so skip this test
if self.isp.input_mode == 'cell': return
isp = self.isp
# whitespace after ':' should not screw up indent level
isp.push('if 1: \n x=1')
self.assertEqual(isp.indent_spaces, 4)
isp.push('y=2\n')
self.assertEqual(isp.indent_spaces, 0)
isp.push('if 1:\t\n x=1')
self.assertEqual(isp.indent_spaces, 4)
isp.push('y=2\n')
self.assertEqual(isp.indent_spaces, 0)
def test_dedent_pass(self):
isp = self.isp # shorthand
# should NOT cause dedent
isp.push('if 1:\n passes = 5')
self.assertEqual(isp.indent_spaces, 4)
isp.push('if 1:\n pass')
self.assertEqual(isp.indent_spaces, 0)
isp.push('if 1:\n pass ')
self.assertEqual(isp.indent_spaces, 0)
def test_dedent_raise(self):
isp = self.isp # shorthand
# should NOT cause dedent
isp.push('if 1:\n raised = 4')
self.assertEqual(isp.indent_spaces, 4)
isp.push('if 1:\n raise TypeError()')
self.assertEqual(isp.indent_spaces, 0)
isp.push('if 1:\n raise')
self.assertEqual(isp.indent_spaces, 0)
isp.push('if 1:\n raise ')
self.assertEqual(isp.indent_spaces, 0)
def test_dedent_return(self):
isp = self.isp # shorthand
# should NOT cause dedent
isp.push('if 1:\n returning = 4')
self.assertEqual(isp.indent_spaces, 4)
isp.push('if 1:\n return 5 + 493')
self.assertEqual(isp.indent_spaces, 0)
isp.push('if 1:\n return')
self.assertEqual(isp.indent_spaces, 0)
isp.push('if 1:\n return ')
self.assertEqual(isp.indent_spaces, 0)
isp.push('if 1:\n return(0)')
self.assertEqual(isp.indent_spaces, 0)
def test_push(self):
isp = self.isp
self.assertTrue(isp.push('x=1'))
def test_push2(self):
isp = self.isp
self.assertFalse(isp.push('if 1:'))
for line in [' x=1', '# a comment', ' y=2']:
self.assertTrue(isp.push(line))
def test_push3(self):
isp = self.isp
isp.push('if True:')
isp.push(' a = 1')
self.assertFalse(isp.push('b = [1,'))
def test_replace_mode(self):
isp = self.isp
isp.input_mode = 'cell'
isp.push('x=1')
self.assertEqual(isp.source, 'x=1\n')
isp.push('x=2')
self.assertEqual(isp.source, 'x=2\n')
def test_push_accepts_more(self):
isp = self.isp
isp.push('x=1')
self.assertFalse(isp.push_accepts_more())
def test_push_accepts_more2(self):
# In cell mode, inputs must be fed in whole blocks, so skip this test
if self.isp.input_mode == 'cell': return
isp = self.isp
isp.push('if 1:')
self.assertTrue(isp.push_accepts_more())
isp.push(' x=1')
self.assertTrue(isp.push_accepts_more())
isp.push('')
self.assertFalse(isp.push_accepts_more())
def test_push_accepts_more3(self):
isp = self.isp
isp.push("x = (2+\n3)")
self.assertFalse(isp.push_accepts_more())
def test_push_accepts_more4(self):
# In cell mode, inputs must be fed in whole blocks, so skip this test
if self.isp.input_mode == 'cell': return
isp = self.isp
# When a multiline statement contains parens or multiline strings, we
# shouldn't get confused.
# FIXME: we should be able to better handle de-dents in statements like
# multiline strings and multiline expressions (continued with \ or
# parens). Right now we aren't handling the indentation tracking quite
# correctly with this, though in practice it may not be too much of a
# problem. We'll need to see.
isp.push("if 1:")
isp.push(" x = (2+")
isp.push(" 3)")
self.assertTrue(isp.push_accepts_more())
isp.push(" y = 3")
self.assertTrue(isp.push_accepts_more())
isp.push('')
self.assertFalse(isp.push_accepts_more())
def test_push_accepts_more5(self):
# In cell mode, inputs must be fed in whole blocks, so skip this test
if self.isp.input_mode == 'cell': return
isp = self.isp
isp.push('try:')
isp.push(' a = 5')
isp.push('except:')
isp.push(' raise')
self.assertTrue(isp.push_accepts_more())
def test_continuation(self):
isp = self.isp
isp.push("import os, \\")
self.assertTrue(isp.push_accepts_more())
isp.push("sys")
self.assertFalse(isp.push_accepts_more())
def test_syntax_error(self):
isp = self.isp
# Syntax errors immediately produce a 'ready' block, so the invalid
# Python can be sent to the kernel for evaluation with possible ipython
# special-syntax conversion.
isp.push('run foo')
self.assertFalse(isp.push_accepts_more())
def test_unicode(self):
self.isp.push(u"Pérez")
self.isp.push(u'\xc3\xa9')
self.isp.push(u"u'\xc3\xa9'")
class InteractiveLoopTestCase(unittest.TestCase):
"""Tests for an interactive loop like a python shell.
"""
def check_ns(self, lines, ns):
"""Validate that the given input lines produce the resulting namespace.
Note: the input lines are given exactly as they would be typed in an
auto-indenting environment, as mini_interactive_loop above already does
auto-indenting and prepends spaces to the input.
"""
src = mini_interactive_loop(pseudo_input(lines))
test_ns = {}
exec src in test_ns
# We can't check that the provided ns is identical to the test_ns,
# because Python fills test_ns with extra keys (copyright, etc). But
# we can check that the given dict is *contained* in test_ns
for k,v in ns.iteritems():
self.assertEqual(test_ns[k], v)
def test_simple(self):
self.check_ns(['x=1'], dict(x=1))
def test_simple2(self):
self.check_ns(['if 1:', 'x=2'], dict(x=2))
def test_xy(self):
self.check_ns(['x=1; y=2'], dict(x=1, y=2))
def test_abc(self):
self.check_ns(['if 1:','a=1','b=2','c=3'], dict(a=1, b=2, c=3))
def test_multi(self):
self.check_ns(['x =(1+','1+','2)'], dict(x=4))
def test_LineInfo():
"""Simple test for LineInfo construction and str()"""
linfo = isp.LineInfo(' %cd /home')
nt.assert_equals(str(linfo), 'LineInfo [ |%|cd|/home]')
# Transformer tests
def transform_checker(tests, func):
"""Utility to loop over test inputs"""
for inp, tr in tests:
nt.assert_equals(func(inp), tr)
# Data for all the syntax tests in the form of lists of pairs of
# raw/transformed input. We store it here as a global dict so that we can use
# it both within single-function tests and also to validate the behavior of the
# larger objects
syntax = \
dict(assign_system =
[(i,py3compat.u_format(o)) for i,o in \
[(u'a =! ls', "a = get_ipython().getoutput({u}'ls')"),
(u'b = !ls', "b = get_ipython().getoutput({u}'ls')"),
('x=1', 'x=1'), # normal input is unmodified
(' ',' '), # blank lines are kept intact
]],
assign_magic =
[(i,py3compat.u_format(o)) for i,o in \
[(u'a =% who', "a = get_ipython().magic({u}'who')"),
(u'b = %who', "b = get_ipython().magic({u}'who')"),
('x=1', 'x=1'), # normal input is unmodified
(' ',' '), # blank lines are kept intact
]],
classic_prompt =
[('>>> x=1', 'x=1'),
('x=1', 'x=1'), # normal input is unmodified
(' ', ' '), # blank lines are kept intact
('... ', ''), # continuation prompts
],
ipy_prompt =
[('In [1]: x=1', 'x=1'),
('x=1', 'x=1'), # normal input is unmodified
(' ',' '), # blank lines are kept intact
(' ....: ', ''), # continuation prompts
],
# Tests for the escape transformer to leave normal code alone
escaped_noesc =
[ (' ', ' '),
('x=1', 'x=1'),
],
# System calls
escaped_shell =
[(i,py3compat.u_format(o)) for i,o in \
[ (u'!ls', "get_ipython().system({u}'ls')"),
# Double-escape shell, this means to capture the output of the
# subprocess and return it
(u'!!ls', "get_ipython().getoutput({u}'ls')"),
]],
# Help/object info
escaped_help =
[(i,py3compat.u_format(o)) for i,o in \
[ (u'?', 'get_ipython().show_usage()'),
(u'?x1', "get_ipython().magic({u}'pinfo x1')"),
(u'??x2', "get_ipython().magic({u}'pinfo2 x2')"),
(u'?a.*s', "get_ipython().magic({u}'psearch a.*s')"),
(u'?%hist1', "get_ipython().magic({u}'pinfo %hist1')"),
(u'?%%hist2', "get_ipython().magic({u}'pinfo %%hist2')"),
(u'?abc = qwe', "get_ipython().magic({u}'pinfo abc')"),
]],
end_help =
[(i,py3compat.u_format(o)) for i,o in \
[ (u'x3?', "get_ipython().magic({u}'pinfo x3')"),
(u'x4??', "get_ipython().magic({u}'pinfo2 x4')"),
(u'%hist1?', "get_ipython().magic({u}'pinfo %hist1')"),
(u'%hist2??', "get_ipython().magic({u}'pinfo2 %hist2')"),
(u'%%hist3?', "get_ipython().magic({u}'pinfo %%hist3')"),
(u'%%hist4??', "get_ipython().magic({u}'pinfo2 %%hist4')"),
(u'f*?', "get_ipython().magic({u}'psearch f*')"),
(u'ax.*aspe*?', "get_ipython().magic({u}'psearch ax.*aspe*')"),
(u'a = abc?', "get_ipython().set_next_input({u}'a = abc');"
"get_ipython().magic({u}'pinfo abc')"),
(u'a = abc.qe??', "get_ipython().set_next_input({u}'a = abc.qe');"
"get_ipython().magic({u}'pinfo2 abc.qe')"),
(u'a = *.items?', "get_ipython().set_next_input({u}'a = *.items');"
"get_ipython().magic({u}'psearch *.items')"),
(u'plot(a?', "get_ipython().set_next_input({u}'plot(a');"
"get_ipython().magic({u}'pinfo a')"),
(u'a*2 #comment?', 'a*2 #comment?'),
]],
# Explicit magic calls
escaped_magic =
[(i,py3compat.u_format(o)) for i,o in \
[ (u'%cd', "get_ipython().magic({u}'cd')"),
(u'%cd /home', "get_ipython().magic({u}'cd /home')"),
# Backslashes need to be escaped.
(u'%cd C:\\User', "get_ipython().magic({u}'cd C:\\\\User')"),
(u' %magic', " get_ipython().magic({u}'magic')"),
]],
# Quoting with separate arguments
escaped_quote =
[ (',f', 'f("")'),
(',f x', 'f("x")'),
(' ,f y', ' f("y")'),
(',f a b', 'f("a", "b")'),
],
# Quoting with single argument
escaped_quote2 =
[ (';f', 'f("")'),
(';f x', 'f("x")'),
(' ;f y', ' f("y")'),
(';f a b', 'f("a b")'),
],
# Simply apply parens
escaped_paren =
[ ('/f', 'f()'),
('/f x', 'f(x)'),
(' /f y', ' f(y)'),
('/f a b', 'f(a, b)'),
],
# Check that we transform prompts before other transforms
mixed =
[(i,py3compat.u_format(o)) for i,o in \
[ (u'In [1]: %lsmagic', "get_ipython().magic({u}'lsmagic')"),
(u'>>> %lsmagic', "get_ipython().magic({u}'lsmagic')"),
(u'In [2]: !ls', "get_ipython().system({u}'ls')"),
(u'In [3]: abs?', "get_ipython().magic({u}'pinfo abs')"),
(u'In [4]: b = %who', "b = get_ipython().magic({u}'who')"),
]],
)
# multiline syntax examples. Each of these should be a list of lists, with
# each entry itself having pairs of raw/transformed input. The union (with
# '\n'.join() of the transformed inputs is what the splitter should produce
# when fed the raw lines one at a time via push.
syntax_ml = \
dict(classic_prompt =
[ [('>>> for i in range(10):','for i in range(10):'),
('... print i',' print i'),
('... ', ''),
],
],
ipy_prompt =
[ [('In [24]: for i in range(10):','for i in range(10):'),
(' ....: print i',' print i'),
(' ....: ', ''),
],
],
multiline_datastructure =
[ [('>>> a = [1,','a = [1,'),
('... 2]','2]'),
],
],
)
def test_assign_system():
tt.check_pairs(isp.transform_assign_system, syntax['assign_system'])
def test_assign_magic():
tt.check_pairs(isp.transform_assign_magic, syntax['assign_magic'])
def test_classic_prompt():
transform_checker(syntax['classic_prompt'], isp.transform_classic_prompt)
for example in syntax_ml['classic_prompt']:
transform_checker(example, isp.transform_classic_prompt)
def test_ipy_prompt():
transform_checker(syntax['ipy_prompt'], isp.transform_ipy_prompt)
for example in syntax_ml['ipy_prompt']:
transform_checker(example, isp.transform_ipy_prompt)
def test_end_help():
tt.check_pairs(isp.transform_help_end, syntax['end_help'])
def test_escaped_noesc():
tt.check_pairs(isp.transform_escaped, syntax['escaped_noesc'])
def test_escaped_shell():
tt.check_pairs(isp.transform_escaped, syntax['escaped_shell'])
def test_escaped_help():
tt.check_pairs(isp.transform_escaped, syntax['escaped_help'])
def test_escaped_magic():
tt.check_pairs(isp.transform_escaped, syntax['escaped_magic'])
def test_escaped_quote():
tt.check_pairs(isp.transform_escaped, syntax['escaped_quote'])
def test_escaped_quote2():
tt.check_pairs(isp.transform_escaped, syntax['escaped_quote2'])
def test_escaped_paren():
tt.check_pairs(isp.transform_escaped, syntax['escaped_paren'])
class IPythonInputTestCase(InputSplitterTestCase):
"""By just creating a new class whose .isp is a different instance, we
re-run the same test battery on the new input splitter.
In addition, this runs the tests over the syntax and syntax_ml dicts that
were tested by individual functions, as part of the OO interface.
It also makes some checks on the raw buffer storage.
"""
def setUp(self):
self.isp = isp.IPythonInputSplitter(input_mode='line')
def test_syntax(self):
"""Call all single-line syntax tests from the main object"""
isp = self.isp
for example in syntax.itervalues():
for raw, out_t in example:
if raw.startswith(' '):
continue
isp.push(raw+'\n')
out, out_raw = isp.source_raw_reset()
self.assertEqual(out.rstrip(), out_t,
tt.pair_fail_msg.format("inputsplitter",raw, out_t, out))
self.assertEqual(out_raw.rstrip(), raw.rstrip())
def test_syntax_multiline(self):
isp = self.isp
for example in syntax_ml.itervalues():
out_t_parts = []
raw_parts = []
for line_pairs in example:
for lraw, out_t_part in line_pairs:
isp.push(lraw)
out_t_parts.append(out_t_part)
raw_parts.append(lraw)
out, out_raw = isp.source_raw_reset()
out_t = '\n'.join(out_t_parts).rstrip()
raw = '\n'.join(raw_parts).rstrip()
self.assertEqual(out.rstrip(), out_t)
self.assertEqual(out_raw.rstrip(), raw)
class BlockIPythonInputTestCase(IPythonInputTestCase):
# Deactivate tests that don't make sense for the block mode
test_push3 = test_split = lambda s: None
def setUp(self):
self.isp = isp.IPythonInputSplitter(input_mode='cell')
def test_syntax_multiline(self):
isp = self.isp
for example in syntax_ml.itervalues():
raw_parts = []
out_t_parts = []
for line_pairs in example:
for raw, out_t_part in line_pairs:
raw_parts.append(raw)
out_t_parts.append(out_t_part)
raw = '\n'.join(raw_parts)
out_t = '\n'.join(out_t_parts)
isp.push(raw)
out, out_raw = isp.source_raw_reset()
# Match ignoring trailing whitespace
self.assertEqual(out.rstrip(), out_t.rstrip())
self.assertEqual(out_raw.rstrip(), raw.rstrip())
#-----------------------------------------------------------------------------
# Main - use as a script, mostly for developer experiments
#-----------------------------------------------------------------------------
if __name__ == '__main__':
# A simple demo for interactive experimentation. This code will not get
# picked up by any test suite.
from IPython.core.inputsplitter import InputSplitter, IPythonInputSplitter
# configure here the syntax to use, prompt and whether to autoindent
#isp, start_prompt = InputSplitter(), '>>> '
isp, start_prompt = IPythonInputSplitter(), 'In> '
autoindent = True
#autoindent = False
try:
while True:
prompt = start_prompt
while isp.push_accepts_more():
indent = ' '*isp.indent_spaces
if autoindent:
line = indent + raw_input(prompt+indent)
else:
line = raw_input(prompt)
isp.push(line)
prompt = '... '
# Here we just return input so we can use it in a test suite, but a
# real interpreter would instead send it for execution somewhere.
#src = isp.source; raise EOFError # dbg
src, raw = isp.source_raw_reset()
print 'Input source was:\n', src
print 'Raw source was:\n', raw
except EOFError:
print 'Bye'
# Tests for cell magics support
def test_last_blank():
nt.assert_false(isp.last_blank(''))
nt.assert_false(isp.last_blank('abc'))
nt.assert_false(isp.last_blank('abc\n'))
nt.assert_false(isp.last_blank('abc\na'))
nt.assert_true(isp.last_blank('\n'))
nt.assert_true(isp.last_blank('\n '))
nt.assert_true(isp.last_blank('abc\n '))
nt.assert_true(isp.last_blank('abc\n\n'))
nt.assert_true(isp.last_blank('abc\nd\n\n'))
nt.assert_true(isp.last_blank('abc\nd\ne\n\n'))
nt.assert_true(isp.last_blank('abc \n \n \n\n'))
def test_last_two_blanks():
nt.assert_false(isp.last_two_blanks(''))
nt.assert_false(isp.last_two_blanks('abc'))
nt.assert_false(isp.last_two_blanks('abc\n'))
nt.assert_false(isp.last_two_blanks('abc\n\na'))
nt.assert_false(isp.last_two_blanks('abc\n \n'))
nt.assert_false(isp.last_two_blanks('abc\n\n'))
nt.assert_true(isp.last_two_blanks('\n\n'))
nt.assert_true(isp.last_two_blanks('\n\n '))
nt.assert_true(isp.last_two_blanks('\n \n'))
nt.assert_true(isp.last_two_blanks('abc\n\n '))
nt.assert_true(isp.last_two_blanks('abc\n\n\n'))
nt.assert_true(isp.last_two_blanks('abc\n\n \n'))
nt.assert_true(isp.last_two_blanks('abc\n\n \n '))
nt.assert_true(isp.last_two_blanks('abc\n\n \n \n'))
nt.assert_true(isp.last_two_blanks('abc\nd\n\n\n'))
nt.assert_true(isp.last_two_blanks('abc\nd\ne\nf\n\n\n'))
class CellMagicsCommon(object):
def test_whole_cell(self):
src = "%%cellm line\nbody\n"
sp = self.sp
sp.push(src)
nt.assert_equal(sp.cell_magic_parts, ['body\n'])
out = sp.source
ref = u"get_ipython()._run_cached_cell_magic({u}'cellm', {u}'line')\n"
nt.assert_equal(out, py3compat.u_format(ref))
def tearDown(self):
self.sp.reset()
class CellModeCellMagics(CellMagicsCommon, unittest.TestCase):
sp = isp.IPythonInputSplitter(input_mode='cell')
def test_incremental(self):
sp = self.sp
src = '%%cellm line2\n'
sp.push(src)
nt.assert_true(sp.push_accepts_more()) #1
src += '\n'
sp.push(src)
# Note: if we ever change the logic to allow full blank lines (see
# _handle_cell_magic), then the following test should change to true
nt.assert_false(sp.push_accepts_more()) #2
# By now, even with full blanks allowed, a second blank should signal
# the end. For now this test is only a redundancy safety, but don't
# delete it in case we change our mind and the previous one goes to
# true.
src += '\n'
sp.push(src)
nt.assert_false(sp.push_accepts_more()) #3
class LineModeCellMagics(CellMagicsCommon, unittest.TestCase):
sp = isp.IPythonInputSplitter(input_mode='line')
def test_incremental(self):
sp = self.sp
sp.push('%%cellm line2\n')
nt.assert_true(sp.push_accepts_more()) #1
sp.push('\n')
nt.assert_false(sp.push_accepts_more()) #2