Esempio n. 1
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def test_mutex_custom_options():
    r = InputReader()
    meg = r.add_mutually_exclusive_group(dest='rainbow', default='cloudy',
                                         required=True)
    assert meg._dest == 'rainbow'
    assert meg._default == 'cloudy'
    assert meg._required
    with raises(ValueError) as e:
        meg = r.add_mutually_exclusive_group(dest=23)
    assert 'dest must be a str, given' in str(e.value)
    with raises(ValueError) as e:
        meg = r.add_mutually_exclusive_group(required='True')
    assert 'required value must be a bool, given' in str(e.value)
Esempio n. 2
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def test_read_mutex():
    r = InputReader()
    meg = r.add_mutually_exclusive_group()
    meg.add_boolean_key('red')
    meg.add_boolean_key('blue')
    meg.add_boolean_key('green')

    inp = r.read_input(['red'])
    assert inp.red
    assert not inp.blue
    assert not inp.green

    with raises(ReaderError) as e:
        inp = r.read_input(['red', 'blue'])
    assert search(r'Only one of .* may be included', str(e.value))

    # Unfortunately we cannot detect duplicate groups in different meg's
    meg2 = r.add_mutually_exclusive_group()
    meg2.add_boolean_key('red')
Esempio n. 3
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def test_mutex_correct_call():
    r = InputReader()
    meg = r.add_mutually_exclusive_group()
    a = meg.add_boolean_key('red')
    assert a.name == 'red'
    assert a._action
    assert not a._default
    meg.add_boolean_key('blue')
    with raises(ReaderError):
        meg.add_boolean_key('red')
Esempio n. 4
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def test_read_mutex_set_dest_set_required():
    r = InputReader()
    meg = r.add_mutually_exclusive_group(required=True, dest='color')
    meg.add_boolean_key('red')
    meg.add_boolean_key('blue')
    meg.add_boolean_key('green')
    r.add_boolean_key('cyan')

    with raises(ReaderError) as e:
        inp = r.read_input(['cyan'])
    assert search(r'One and only one of .* must be included', str(e.value))
Esempio n. 5
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def test_read_mutex_set_default():
    r = InputReader()
    meg = r.add_mutually_exclusive_group(default='water')
    meg.add_boolean_key('red')
    meg.add_boolean_key('blue')
    meg.add_boolean_key('green')
    inp = r.read_input(['red'])
    assert inp.red
    assert inp.blue == 'water'
    assert inp.green == 'water'
    inp = r.read_input([])
    assert inp.red == 'water'
    assert inp.blue == 'water'
    assert inp.green == 'water'

    # Using default=SUPPRESS was the intended use case of default for meg's
    meg = r.add_mutually_exclusive_group(default=SUPPRESS)
    meg.add_boolean_key('pink')
    meg.add_boolean_key('gray')
    meg.add_boolean_key('cyan')
    inp = r.read_input(['pink'])
    assert inp.pink
    assert 'gray' not in inp
    assert 'cyan' not in inp
Esempio n. 6
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def test_read_mutex_set_required():
    r = InputReader()
    meg = r.add_mutually_exclusive_group(required=True)
    meg.add_boolean_key('red')
    meg.add_boolean_key('blue')
    meg.add_boolean_key('green')

    inp = r.read_input(['blue'])
    assert inp.blue
    assert not inp.red
    assert not inp.green

    with raises(ReaderError) as e:
        inp = r.read_input([])
    assert search(r'One and only one of .* must be included', str(e.value))
Esempio n. 7
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def test_read_mutex_set_dest():
    r = InputReader()
    # This is the best way to use meg's
    meg = r.add_mutually_exclusive_group(dest='color')
    meg.add_boolean_key('red', action='red')
    meg.add_boolean_key('blue', action='blue')
    meg.add_boolean_key('green', action='green')
    meg.add_boolean_key('pink', action='pink')
    meg.add_boolean_key('gray', action='pink')
    meg.add_boolean_key('cyan', action='cyan')
    r.add_boolean_key('white')
    inp = r.read_input(['cyan', 'white'])
    assert inp.color == 'cyan'
    assert inp.white
    assert 'red' not in inp
    assert 'blue' not in inp
    assert 'green' not in inp
    assert 'pink' not in inp
    assert 'gray' not in inp
    assert 'cyan' not in inp
Esempio n. 8
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def read_input(input_file):
    '''Defines what to expect from the input file and then
    reads it in.'''

    # Creates an input reader instance
    reader = InputReader(default=SUPPRESS)

    # Rate parameter, either rate or lifetime, not both
    rate = reader.add_mutually_exclusive_group(required=True)
    # The units are s, ns, ps, or fs.  The default is ps.
    rate.add_line_key('lifetime', type=float,
                      glob={'len' : '?',
                            'type' : ('ps', 'fs', 'ns', 's'),
                            'default' : 'ps'})
    rate.add_line_key('rate', type=float,
                      glob={'len' : '?',
                            'type' : ('thz', 'phz', 'ghz', 'hz'),
                            'default' : 'thz'})

    # The range of the X-axis
    reader.add_line_key('xlim', type=[int, int], default=(1900, 2000))
    reader.add_boolean_key('reverse', action=True, default=False)

    # Read in the raw data.  
    reader.add_line_key('raw', type=[], glob={'len':'*', 'join':True, },
                               default=None, case=True)

    # Read in the peak data.  The wavenumber and height is required.
    # The Lorentzian and Gaussian widths are defaulted to 10 if not given.
    floatkw = {'type' : float, 'default' : 10.0}
    reader.add_line_key('peak', required=True, repeat=True, type=[float,float],
                                keywords={'g':floatkw, 'l':floatkw,
                                          'num' : {'type':int,'default':-1}})

    # Read the exchange information.
    reader.add_line_key('exchange', repeat=True, type=[int, int],
                                    glob={'type' : float,
                                          'default' : 1.0,
                                          'len' : '?'})
    reader.add_boolean_key('nosym', action=False, default=True,
                           dest='symmetric_exchange')

    # Actually read the input file
    args = reader.read_input(input_file)

    # Make sure the filename was given correctly and read in data
    if args.raw:
        args.add('rawName', args.raw)
        args.raw = loadtxt(abs_file_path(args.raw))

    # Make the output file path absolute if given
    args.data = abs_file_path(args.data) if 'data' in args else ''

    if 'save_plot_script' in args:
        args.save_plot_script = abs_file_path(args.save_plot_script)
    else:
        args.save_plot_script = ''

    # Adjust the input rate or lifetime to wavenumbers
    if 'lifetime' in args:
        convert = { 'ps' : 1E-12, 'ns' : 1E-9, 'fs' : 1E-15, 's' : 1 }
        args.add('k', 1 / ( convert[args.lifetime[1]] * args.lifetime[0] ))
    else:
        convert = { 'thz' : 1E12, 'ghz' : 1E9, 'phz' : 1E15, 'hz' : 1 }
        args.add('k', convert[args.rate[1]] * args.rate[0])
    args.k *= HZ2WAVENUM / ( 2 * pi )

    # Parse the vibrational input
    num, vib, Gamma_Lorentz, Gamma_Gauss, heights, rel_rates, num_given = (
                                                    [], [], [], [], [], [], [])
    for peak in args.peak:
        # Vibration #
        num.append(peak[2]['num'])
        num_given.append(False if peak[2]['num'] < 0 else True)
        # Angular frequency
        vib.append(peak[0])
        # Relative peak heights
        heights.append(peak[1])
        # Default Gaussian or Lorentzian width or relative rate
        Gamma_Lorentz.append(peak[2]['l'])
        Gamma_Gauss.append(peak[2]['g'])

    # Either all or none of the numbers must be given explicitly
    if not (all(num_given) or not any(num_given)):
        raise ReaderError('All or none of the peaks must '
                          'be given numbers explicitly')
    # If the numbers were give, make sure there are no duplicates
    if all(num_given):
        if len(num) != len(set(num)):
            raise ReaderError('Duplicate peaks cannot be given')
    # If none were given, number automatically
    else:
        num = range(1, len(num)+1, 1)

    args.add('num', array(num))
    args.add('vib', array(vib))
    args.add('heights', array(heights))
    args.add('Gamma_Lorentz', array(Gamma_Lorentz))
    args.add('Gamma_Gauss', array(Gamma_Gauss))

    # Set up the exchanges
    # Make sure the each exchange number appears in num.
    num = set(num)
    ex = []
    rates = []
    string = 'Requested peak {0} in exchange does not exist'
    if 'exchange' in args:
        for exchange in args.exchange:
            p1 = exchange[0]
            if p1 not in num:
                raise ReaderError(string.format(p1))
            p2 = exchange[1]
            if p2 not in num:
                raise ReaderError(string.format(p2))
            if p1 == p2 and args.symmetric_exchange:
                raise ReaderError('Self exchange is not allowed')
            rate = exchange[2]
            # Offset the peak number by one to match python indicies
            ex.append([p1-1, p2-1])
            rates.append(rate)
    else:
        ex = []
        rates = []
    args.add('exchanges', array(ex, dtype=int))
    args.add('exchange_rates', array(rates))

    # Make sure the xlimits are ascending
    try:
        range_check(args.xlim[0], args.xlim[1])
    except ValueError:
        raise ReaderError('In xrange, the low value must '
                          'less than the high value')

    return args
Esempio n. 9
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def test_create_mutex_group():
    r = InputReader()
    meg = r.add_mutually_exclusive_group()
    assert meg._default is None
    assert meg._dest is None
    assert not meg._required
Esempio n. 10
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def test_mutex_custom_options_str():
    r = InputReader()
    meg = r.add_mutually_exclusive_group(dest=str('rainbow'),
                                         default=str('cloudy'))
    assert meg._dest == 'rainbow'
    assert meg._default == 'cloudy'