def numwordsen(pre, value): value = value.strip() value = value.lower() if value in { "nil", "none", "", "no", "null" }: value = 0 else: value = number_parser.parse(value) f = Float(float(value) * pre.scale) if pre.unit: f.unit = pre.unit return f
def parse_durwordsen(val): delta = datetime.timedelta() num = None val = number_parser.parse(val) val = val.replace("\xa0", " ") res = re.split(r'[ ,.:;-]+', val) for v in res: v = v.lower() if num == None: if v in {"and", "plus", "with", "then"}: continue try: num = int(v) except: raise RuntimeError("Not a number: %s" % v) else: if v == "year" or v == "years": delta += datetime.timedelta(days=(num * 356)) elif v == "month" or v == "months": delta += datetime.timedelta(days=(num * 30)) elif v == "day" or v == "days": delta += datetime.timedelta(days=num) elif v == "hour" or v == "hours": delta += datetime.timedelta(hours=num) elif v == "minute" or v == "minutes": delta += datetime.timedelta(minutes=num) elif v == "second" or v == "seconds": delta += datetime.timedelta(seconds=num) else: raise RuntimeError("Stalled on token %s" % v) num = None return delta
def test_parse_ambiguity_in_multipliers(expected, test_input): assert parse(test_input, LANG) == expected
def test_parse_ambiguity_in_separators(expected, test_input): assert parse(test_input, LANG) == expected
def test_parse_basic_sentences(expected, test_input): assert parse(test_input, LANG) == expected
def generate_signal(self, signal=None): option = self.selectedFunction.get() option = option.encode('ascii', 'ignore') if signal == None: if option == "szum gaussowski": signal = noise_generator.gaussian( name=self.nameEntry.get(), A=number_parser.parse(self.amplitudeEntry.get()), t1=number_parser.parse(self.t1Entry.get()), d=number_parser.parse(self.dEntry.get()), sampling_freq=number_parser.parse( self.sampFreqEntry.get())) elif option == "szum o rozkadzie jednostajnym": signal = noise_generator.uniform( name=self.nameEntry.get(), A=number_parser.parse(self.amplitudeEntry.get()), t1=number_parser.parse(self.t1Entry.get()), d=number_parser.parse(self.dEntry.get()), sampling_freq=number_parser.parse( self.sampFreqEntry.get())) elif option == "sinusoidalny": signal = sig_gen.sine( name=self.nameEntry.get(), A=number_parser.parse(self.amplitudeEntry.get()), T=number_parser.parse(self.TEntry.get()), t1=number_parser.parse(self.t1Entry.get()), d=number_parser.parse(self.dEntry.get()), sampling_freq=number_parser.parse( self.sampFreqEntry.get())) elif option == "sin. wyprostowany jednopowkowo": signal = sig_gen.half_wave_rect_sine( name=self.nameEntry.get(), A=number_parser.parse(self.amplitudeEntry.get()), T=number_parser.parse(self.TEntry.get()), t1=number_parser.parse(self.t1Entry.get()), d=number_parser.parse(self.dEntry.get()), sampling_freq=number_parser.parse( self.sampFreqEntry.get())) elif option == "sin. wyprostowany dwupowkowo": signal = sig_gen.full_wave_rect_sine( name=self.nameEntry.get(), A=number_parser.parse(self.amplitudeEntry.get()), T=number_parser.parse(self.TEntry.get()), t1=number_parser.parse(self.t1Entry.get()), d=number_parser.parse(self.dEntry.get()), sampling_freq=number_parser.parse( self.sampFreqEntry.get())) elif option == "prostoktny": signal = sig_gen.square( name=self.nameEntry.get(), A=number_parser.parse(self.amplitudeEntry.get()), T=number_parser.parse(self.TEntry.get()), kW=number_parser.parse(self.KwEntry.get()), t1=number_parser.parse(self.t1Entry.get()), d=number_parser.parse(self.dEntry.get()), sampling_freq=number_parser.parse( self.sampFreqEntry.get())) elif option == "prostoktny symetryczny": signal = sig_gen.square_symmetrical( name=self.nameEntry.get(), A=number_parser.parse(self.amplitudeEntry.get()), T=number_parser.parse(self.TEntry.get()), kW=number_parser.parse(self.KwEntry.get()), t1=number_parser.parse(self.t1Entry.get()), d=number_parser.parse(self.dEntry.get()), sampling_freq=number_parser.parse( self.sampFreqEntry.get())) elif option == "trjktny": signal = sig_gen.triangular( name=self.nameEntry.get(), A=number_parser.parse(self.amplitudeEntry.get()), T=number_parser.parse(self.TEntry.get()), kW=number_parser.parse(self.KwEntry.get()), t1=number_parser.parse(self.t1Entry.get()), d=number_parser.parse(self.dEntry.get()), sampling_freq=number_parser.parse( self.sampFreqEntry.get())) elif option == "skok jednostkowy": signal = sig_gen.step_function( name=self.nameEntry.get(), A=number_parser.parse(self.amplitudeEntry.get()), t1=number_parser.parse(self.t1Entry.get()), d=number_parser.parse(self.dEntry.get()), sampling_freq=number_parser.parse( self.sampFreqEntry.get()), tS=number_parser.parse(self.tsEntry.get())) elif option == "impuls jednostkowy": signal = sig_gen.kronecker( name=self.nameEntry.get(), A=number_parser.parse(self.amplitudeEntry.get()), nS=number_parser.parse(self.nSEntry.get()), n1=number_parser.parse(self.n1Entry.get()), l=number_parser.parse(self.dEntry.get()), sampling_freq=number_parser.parse( self.sampFreqEntry.get())) elif option == "szum impulsowy": signal = noise_generator.impulse( name=self.nameEntry.get(), A=number_parser.parse(self.amplitudeEntry.get()), t1=number_parser.parse(self.t1Entry.get()), d=number_parser.parse(self.dEntry.get()), sampling_freq=number_parser.parse( self.sampFreqEntry.get()), p=number_parser.parse(self.pEntry.get())) self.formWindow.destroy() self.add_to_menu_grid(signal, signal.name) self.draw_signal(signal)
def test_parse(expected, test_input): assert parse(test_input, LANG) == expected
def test_parse_basic_sentences(self, expected, test_input): assert parse(test_input) == expected
def test_parse_case_of_string(expected, test_input, lang): assert parse(test_input, lang) == expected
def test_parse_basic_sentences(expected, test_input, lang): assert parse(test_input, lang) == expected
def test_parse_sentences_ordinal(expected, test_input, lang): assert parse(test_input, lang) == expected
def test_parse_sentences_ordinal(self, expected, test_input): assert parse(test_input, LANG) == expected
def cvt(row, lang): return parse(row, language=lang)
def parseNumber(): data = request.form['data'] ret = str(parse(data)) ret = ret.replace(" ", "") return ret
def test_parse_basic_sentences_lang_auto(expected, test_input): assert parse(test_input) == expected