# -*- 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_break(self): isp = self.isp # shorthand # should NOT cause dedent isp.push('while 1:\n breaks = 5') self.assertEqual(isp.indent_spaces, 4) isp.push('while 1:\n break') self.assertEqual(isp.indent_spaces, 0) isp.push('while 1:\n break ') self.assertEqual(isp.indent_spaces, 0) def test_dedent_continue(self): isp = self.isp # shorthand # should NOT cause dedent isp.push('while 1:\n continues = 5') self.assertEqual(isp.indent_spaces, 4) isp.push('while 1:\n continue') self.assertEqual(isp.indent_spaces, 0) isp.push('while 1:\n continue ') 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"PĂ©rez") self.isp.push(u'\xc3\xa9') self.isp.push(u"u'\xc3\xa9'") def test_line_continuation(self): """ Test issue #2108.""" isp = self.isp # A blank line after a line continuation should not accept more isp.push("1 \\\n\n") self.assertFalse(isp.push_accepts_more()) # Whitespace after a \ is a SyntaxError. The only way to test that # here is to test that push doesn't accept more (as with # test_syntax_error() above). isp.push(r"1 \ ") self.assertFalse(isp.push_accepts_more()) # Even if the line is continuable (c.f. the regular Python # interpreter) isp.push(r"(1 \ ") self.assertFalse(isp.push_accepts_more()) 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()) def test_syntax_multiline_cell(self): isp = self.isp for example in syntax_ml.itervalues(): out_t_parts = [] for line_pairs in example: raw = '\n'.join(r for r, _ in line_pairs) out_t = '\n'.join(t for _,t in line_pairs) out = isp.transform_cell(raw) # Match ignoring trailing whitespace self.assertEqual(out.rstrip(), out_t.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