def testLexMidlineModeExcerpt(self):
     r_normal = pythonSource(incompletePythonCode)
     r_mid_line = pythonSource(incompletePythonCode, mid_line=True)
     self.assertEquals(len(r_normal), 13)
     self.assertEquals(len(r_mid_line), 11)
     self.assertEquals(r_normal[-1].type, 'ENDMARKER')
     self.assertEquals(r_normal[-2].type, 'DEDENT')
     self.assertEquals(r_mid_line[-1].value, 'ran')
 def testLexMidlineModeSingleLine(self):
     r_normal = pythonSource(somePythonCode)
     r_mid_line = pythonSource(somePythonCode, mid_line=True)
     # This small one line example has no indent or anything.
     self.assertEquals(len(r_normal), 9)
     self.assertEquals(len(r_mid_line), 8)
     self.assertEquals(r_normal[-1].type, 'ENDMARKER')
     self.assertNotEquals(r_mid_line[-1].type, 'ENDMARKER')
 def testLexMidlineModeExcerpt(self):
     r_normal = pythonSource(incompletePythonCode)
     r_mid_line = pythonSource(incompletePythonCode, mid_line=True)
     self.assertEquals(len(r_normal), 13)
     self.assertEquals(len(r_mid_line), 11)
     self.assertEquals(r_normal[-1].type, 'ENDMARKER')
     self.assertEquals(r_normal[-2].type, 'DEDENT')
     self.assertEquals(r_mid_line[-1].value, 'ran')
 def testLexMidlineModeSingleLine(self):
     r_normal = pythonSource(somePythonCode)
     r_mid_line = pythonSource(somePythonCode, mid_line=True)
     # This small one line example has no indent or anything.
     self.assertEquals(len(r_normal), 9)
     self.assertEquals(len(r_mid_line), 8)
     self.assertEquals(r_normal[-1].type, 'ENDMARKER')
     self.assertNotEquals(r_mid_line[-1].type, 'ENDMARKER')
 def testDeleteOne(self):
     r = pythonSource(lotsOfPythonCode)
     x = r.pop(1)
     self.assertEquals(x.value, 'def')
     r.check()
     r.pop(6)
     r.check()
     r.pop(1)
     r.check()
     r.pop(1)
     r.check()
     r.pop(1)
     r.check()
     r.pop(1)
     r.check()
     r.pop(1)
     r.check()
     r.pop(1)
     r.check()
     r.pop(1)
     r.check()
     r.pop(1)
     r.check()
     r.pop(1)
     r.check()
     r.pop(1)
     r.check()
 def testDeleteOne(self):
     r = pythonSource(lotsOfPythonCode)
     x = r.pop(1)
     self.assertEquals(x.value, 'def')
     r.check()
     r.pop(6)
     r.check()
     r.pop(1)
     r.check()
     r.pop(1)
     r.check()
     r.pop(1)
     r.check()
     r.pop(1)
     r.check()
     r.pop(1)
     r.check()
     r.pop(1)
     r.check()
     r.pop(1)
     r.check()
     r.pop(1)
     r.check()
     r.pop(1)
     r.check()
     r.pop(1)
     r.check()
 def testDeleteOneTwo(self):
     r = pythonSource(codeWithDeleteFailure)
     x = r.pop(2)
     r.check()
     r.pop(2)
     r.check()
     r.pop(2)
     r.check()
 def testDeleteOneTwo(self):
     r = pythonSource(codeWithDeleteFailure)
     x = r.pop(2)
     r.check()
     r.pop(2)
     r.check()
     r.pop(2)
     r.check()
 def testLexExpectedToken(self):
     r = pythonSource(somePythonCode)
     self.assertEquals(r[0].end[0], 1)
     self.assertEquals(r[0].end[1], 5)
     self.assertEquals(r[0].start[0], 1)
     self.assertEquals(r[0].start[1], 0)
     self.assertEquals(r[0].type, 'NAME')
     self.assertEquals(r[0].value, 'print')
 def testLexExpectedToken(self):
     r = pythonSource(somePythonCode)
     self.assertEquals(r[0].end[0], 1)
     self.assertEquals(r[0].end[1], 5)
     self.assertEquals(r[0].start[0], 1)
     self.assertEquals(r[0].start[1], 0)
     self.assertEquals(r[0].type, 'NAME')
     self.assertEquals(r[0].value, 'print')
 def testLexExpectedFormat(self):
     r = pythonSource(somePythonCode)
     self.assertTrue(isinstance(r, ucSource))
     self.assertTrue(isinstance(r[0], ucLexeme))
     self.assertTrue(isinstance(r[0].end, tuple))
     self.assertTrue(isinstance(r[0].end.l, int))
     self.assertTrue(isinstance(r[0].end.c, int))
     self.assertTrue(isinstance(r[0].start, tuple))
     self.assertTrue(isinstance(r[0].start[0], int))
     self.assertTrue(isinstance(r[0].start[1], int))
     self.assertTrue(isinstance(r[0].type, str))
     self.assertTrue(isinstance(r[0].value, str))
 def testLexExpectedFormat(self):
     r = pythonSource(somePythonCode)
     self.assertTrue(isinstance(r, ucSource))
     self.assertTrue(isinstance(r[0], ucLexeme))
     self.assertTrue(isinstance(r[0].end, tuple))
     self.assertTrue(isinstance(r[0].end.l, int))
     self.assertTrue(isinstance(r[0].end.c, int))
     self.assertTrue(isinstance(r[0].start, tuple))
     self.assertTrue(isinstance(r[0].start[0], int))
     self.assertTrue(isinstance(r[0].start[1], int))
     self.assertTrue(isinstance(r[0].type, str))
     self.assertTrue(isinstance(r[0].value, str))
 def testPopBug(self):
     # AssertionError: [('OP', '=', (76, 44), (76, 45)), ('NEWLINE', '\n', (76, 3), (76, 4))]
     r = pythonSource("a=1+2\na")
     r.pop(4)
     r.check()
     r = pythonSource("a=1+2\na")
     r.pop(5)
     r.check()
     r = pythonSource("a=1+2\n\n")
     r.pop(4)
     r.check()
     r = pythonSource("a=1\n\n")
     r.pop(2)
     r.check()
     r = pythonSource("for _ in range(0, x):\n\ta=1\n\n")
     x = r.pop(14)
     r.check()
     self.assertEquals(x.value, '1')
     r = pythonSource("for _ in range(0, x):\n\ta=1\n\n")
     x = r.pop(9)
     r.check()
     self.assertEquals(x.value, ':')
 def testPopBug(self):
     # AssertionError: [('OP', '=', (76, 44), (76, 45)), ('NEWLINE', '\n', (76, 3), (76, 4))]
     r = pythonSource("a=1+2\na")
     r.pop(4)
     r.check()
     r = pythonSource("a=1+2\na")
     r.pop(5)
     r.check()
     r = pythonSource("a=1+2\n\n")
     r.pop(4)
     r.check()
     r = pythonSource("a=1\n\n")
     r.pop(2)
     r.check()
     r = pythonSource("for _ in range(0, x):\n\ta=1\n\n")
     x = r.pop(14)
     r.check()
     self.assertEquals(x.value, '1')
     r = pythonSource("for _ in range(0, x):\n\ta=1\n\n")
     x = r.pop(9)
     r.check()
     self.assertEquals(x.value, ':')
 def testLexExpectedLength(self):
     r = pythonSource(somePythonCode)
     self.assertEquals(len(r), 9)
 def testPoppin(self):
     r = pythonSource("1+2")
     r.pop(0)
     r.pop(0)
     r.pop(0)
 def testExclusiveEnd(self):
     r = pythonSource("1+2")
     self.assertTrue(r[0].start.c + 1 == r[0].end.c) # First token is r[0]
     self.assertTrue(r[2].start.c + 1 == r[2].end.c)
 def testStringifyStandard(self):
     self.assertEquals(str(pythonSource(someLexemes)[0]), 'print')
     self.assertEquals(str(pythonSource(someLexemes)[8]), '<ENDMARKER>')
     self.assertEquals(str(pythonLexeme.fromDict(indentLexeme)), '<INDENT>')
 def testExclusiveEnd(self):
     r = pythonSource("1+2")
     self.assertTrue(r[0].start.c + 1 == r[0].end.c)  # First token is r[0]
     self.assertTrue(r[2].start.c + 1 == r[2].end.c)
 def testColumns(self):
     r = pythonSource(lotsOfPythonCode)
     self.assertEquals(r[1].columns(), 3)  # this should be the "def" token
     self.assertEquals(r[0].lines(), 0)
 def testPoppin(self):
     r = pythonSource("1+2")
     r.pop(0)
     r.pop(0)
     r.pop(0)
 def testStringifyStandard(self):
     self.assertEquals(str(pythonSource(someLexemes)[0]), 'print')
     self.assertEquals(str(pythonSource(someLexemes)[8]), '<ENDMARKER>')
     self.assertEquals(str(pythonLexeme.fromDict(indentLexeme)), '<INDENT>')
 def testLexDeLex(self):
     self.assertEquals(lotsOfPythonCode,
                       (pythonSource(lotsOfPythonCode).deLex()))
     self.assertEquals(codeWithComments,
                       (pythonSource(codeWithComments).deLex()))
 def testLexDeLex(self):
     self.assertEquals(lotsOfPythonCode, (pythonSource(lotsOfPythonCode).deLex()))
     self.assertEquals(codeWithComments, (pythonSource(codeWithComments).deLex()))
 def testColumns(self):
     r = pythonSource(lotsOfPythonCode)
     self.assertEquals(r[1].columns(), 3) # this should be the "def" token
     self.assertEquals(r[0].lines(), 0)
 def testLexExpectedLength(self):
     r = pythonSource(somePythonCode)
     self.assertEquals(len(r), 9)
import unittest
from logging import debug, info, warning, error

from estimatecharm.unnaturalCode import *
from estimatecharm.pythonSource import *
from estimatecharm.estimateCharm import *

import os, os.path, sys, shutil, token, gc
from tempfile import *

from estimatecharm.ucTestData import *

# Helper. Given a list of lexemes, gives the stringified version
# of the ith lexeme.
strlex = lambda lexemes, i: str(pythonSource(lexemes)[i])
# Helper. Same as strlex, but takes a single dict representing a lexeme.
strlexd = lambda lexeme: str(pythonLexeme.fromDict(lexeme))

logging.getLogger(__name__).setLevel(logging.DEBUG)


class testPythonLexical(unittest.TestCase):
    @classmethod
    def setUpClass(self):
        pass
    def testLexExpectedLength(self):
        r = pythonSource(somePythonCode)
        self.assertEquals(len(r), 9)
    def testLexExpectedFormat(self):
        r = pythonSource(somePythonCode)
import unittest
from logging import debug, info, warning, error

from estimatecharm.unnaturalCode import *
from estimatecharm.pythonSource import *
from estimatecharm.estimateCharm import *

import os, os.path, sys, shutil, token, gc
from tempfile import *

from estimatecharm.ucTestData import *

# Helper. Given a list of lexemes, gives the stringified version
# of the ith lexeme.
strlex = lambda lexemes, i: str(pythonSource(lexemes)[i])
# Helper. Same as strlex, but takes a single dict representing a lexeme.
strlexd = lambda lexeme: str(pythonLexeme.fromDict(lexeme))

logging.getLogger(__name__).setLevel(logging.DEBUG)


class testPythonLexical(unittest.TestCase):
    @classmethod
    def setUpClass(self):
        pass

    def testLexExpectedLength(self):
        r = pythonSource(somePythonCode)
        self.assertEquals(len(r), 9)