def __init__(self, *args):
from abjad.tools import indicatortools
if len(args) == 1 and isinstance(args[0], type(self)):
self._tempo_indication = args[0].tempo_indication
self._proportional_notation_duration = \
args[0].proportional_notation_duration
elif len(args) == 2:
tempo = args[0]
if isinstance(tempo, tuple):
tempo = indicatortools.Tempo(*tempo)
tempo_indication = tempo
proportional_notation_duration = durationtools.Duration(args[1])
self._tempo_indication = tempo_indication
self._proportional_notation_duration = \
proportional_notation_duration
elif len(args) == 0:
tempo = indicatortools.Tempo()
proportional_notation_duration = durationtools.Duration(1, 68)
self._tempo_indication = tempo
self._proportional_notation_duration = \
proportional_notation_duration
else:
message = 'can not initialize spacing indication from {!r}'
message = message.format(args)
raise ValueError(message)
def quarters_per_minute(self):
r'''Quarters per minute of tempo.
::
>>> tempo = Tempo(Duration(1, 8), 52)
>>> tempo.quarters_per_minute
Fraction(104, 1)
Returns tuple when tempo `units_per_minute` is a range.
Returns none when tempo is imprecise.
Returns fraction otherwise.
'''
if self.is_imprecise:
return None
if isinstance(self.units_per_minute, tuple):
low = durationtools.Duration(1, 4) / self.duration * \
self.units_per_minute[0]
high = durationtools.Duration(1, 4) / self.duration * \
self.units_per_minute[1]
return (low, high)
result = durationtools.Duration(1, 4) / self.duration * \
self.units_per_minute
return fractions.Fraction(result)
def make_skips(
written_duration,
multiplied_durations,
):
'''Make `written_duration` skips with `multiplied_durations`:
::
>>> scoretools.make_skips(
... Duration(1, 4), [(1, 2), (1, 3), (1, 4), (1, 5)])
Selection(Skip('s4 * 2'), Skip('s4 * 4/3'), Skip('s4 * 1'), Skip('s4 * 4/5'))
Useful for making invisible layout voices.
Returns selection.
'''
from abjad.tools import scoretools
# initialize skips and written duration
skips = []
written_duration = durationtools.Duration(written_duration)
# make skips
for multiplied_duration in multiplied_durations:
multiplied_duration = durationtools.Duration(multiplied_duration)
skip = scoretools.Skip(written_duration)
multiplier = multiplied_duration / written_duration
attach(multiplier, skip)
skips.append(skip)
# return skips
skips = selectiontools.Selection(skips)
return skips
def duration_to_milliseconds(self, duration):
r'''Gets millisecond value of `duration` under a given tempo.
.. container:: example
::
>>> duration = (1, 4)
>>> tempo = Tempo((1, 4), 60)
>>> tempo.duration_to_milliseconds(duration)
Duration(1000, 1)
Returns duration.
'''
duration = durationtools.Duration(duration)
# TODO: rewrite formula without line breaks;
# use two or three temporary variables instead.
whole_note_duration = 1000 \
* durationtools.Multiplier(
self.duration.denominator,
self.duration.numerator,
) \
* durationtools.Multiplier(
60,
self.units_per_minute,
)
return durationtools.Duration(duration * whole_note_duration)
def __init__(
self,
beatspan=None,
offset_in_ms=None,
search_tree=None,
tempo=None,
):
from abjad.tools import quantizationtools
beatspan = beatspan or durationtools.Duration(0)
beatspan = durationtools.Duration(beatspan)
offset_in_ms = offset_in_ms or durationtools.Duration(0)
offset_in_ms = durationtools.Offset(offset_in_ms)
if search_tree is None:
search_tree = quantizationtools.UnweightedSearchTree()
assert isinstance(search_tree, quantizationtools.SearchTree)
tempo = tempo or indicatortools.Tempo(durationtools.Duration(1, 4), 60)
#tempo = indicatortools.Tempo(tempo)
if isinstance(tempo, tuple):
tempo = indicatortools.Tempo(*tempo)
assert not tempo.is_imprecise
q_events = []
q_grids = []
self._beatspan = beatspan
self._distances = {}
self._offset_in_ms = offset_in_ms
self._q_events = q_events
self._q_grid = None
self._q_grids = q_grids
self._search_tree = search_tree
self._tempo = tempo
def __init__(
self,
minimum_duration=None,
maximum_duration=None,
minimum_written_pitch=None,
maximum_written_pitch=None,
):
if minimum_duration is None:
self._minimum_duration = minimum_duration
else:
self._minimum_duration = durationtools.Duration(minimum_duration)
if maximum_duration is None:
self._maximum_duration = maximum_duration
else:
self._maximum_duration = durationtools.Duration(maximum_duration)
if minimum_written_pitch is None:
self._minimum_written_pitch = minimum_written_pitch
else:
self._minimum_written_pitch = \
pitchtools.NamedPitch(minimum_written_pitch)
if maximum_written_pitch is None:
self._maximum_written_pitch = maximum_written_pitch
else:
self._maximum_written_pitch = \
pitchtools.NamedPitch(maximum_written_pitch)
def apply_expressive_marks(score):
r'''Applies expressive marks to score.
'''
voice = score['First Violin Voice']
markup = markuptools.Markup(r'\left-column { div. \line { con sord. } }',
Up)
attach(markup, voice[6][1])
markup = markuptools.Markup('sim.', Up)
attach(markup, voice[8][0])
markup = markuptools.Markup('uniti', Up)
attach(markup, voice[58][3])
markup = markuptools.Markup('div.', Up)
attach(markup, voice[59][0])
markup = markuptools.Markup('uniti', Up)
attach(markup, voice[63][3])
voice = score['Second Violin Voice']
markup = markuptools.Markup('div.', Up)
attach(markup, voice[7][0])
markup = markuptools.Markup('uniti', Up)
attach(markup, voice[66][1])
markup = markuptools.Markup('div.', Up)
attach(markup, voice[67][0])
markup = markuptools.Markup('uniti', Up)
attach(markup, voice[74][0])
voice = score['Viola Voice']
markup = markuptools.Markup('sole', Up)
attach(markup, voice[8][0])
voice = score['Cello Voice']
markup = markuptools.Markup('div.', Up)
attach(markup, voice[10][0])
markup = markuptools.Markup('uniti', Up)
attach(markup, voice[74][0])
markup = markuptools.Markup('uniti', Up)
attach(markup, voice[84][1])
markup = markuptools.Markup(r'\italic { espr. }', Down)
attach(markup, voice[86][0])
markup = markuptools.Markup(r'\italic { molto espr. }', Down)
attach(markup, voice[88][1])
voice = score['Bass Voice']
markup = markuptools.Markup('div.', Up)
attach(markup, voice[14][0])
markup = markuptools.Markup(r'\italic { espr. }', Down)
attach(markup, voice[86][0])
mutate(voice[88][:]).split(
[durationtools.Duration(1, 1),
durationtools.Duration(1, 2)])
markup = markuptools.Markup(r'\italic { molto espr. }', Down)
attach(markup, voice[88][1])
markup = markuptools.Markup('uniti', Up)
attach(markup, voice[99][1])
strings_staff_group = score['Strings Staff Group']
for voice in iterate(strings_staff_group).by_class(scoretools.Voice):
markup = markuptools.Markup(r'\italic { (non dim.) }', Down)
attach(markup, voice[102][0])
def make_notes_with_multiplied_durations(
pitch,
written_duration,
multiplied_durations,
):
'''Make `written_duration` notes with `pitch` and `multiplied_durations`:
::
>>> args = [0, Duration(1, 4), [(1, 2), (1, 3), (1, 4), (1, 5)]]
>>> scoretools.make_notes_with_multiplied_durations(*args)
Selection(Note("c'4 * 2"), Note("c'4 * 4/3"), Note("c'4 * 1"), Note("c'4 * 4/5"))
Useful for making spatially positioned notes.
Returns list of notes.
'''
from abjad.tools import scoretools
from abjad.tools import selectiontools
# initialize input
written_duration = durationtools.Duration(written_duration)
# make notes
notes = []
for multiplied_duration in multiplied_durations:
multiplied_duration = durationtools.Duration(multiplied_duration)
note = scoretools.Note(pitch, written_duration)
multiplier = multiplied_duration / written_duration
attach(multiplier, note)
notes.append(note)
# return notes
notes = selectiontools.Selection(notes)
return notes
def make_windungen_score(
bandwidth=3,
compress_reflections=True,
leaf_duration=durationtools.Duration(1, 16),
length=32,
pitches=('c', 'd', 'e'),
staff_count=12,
):
from experimental.demos.windungen.WindungenScoreTemplate import WindungenScoreTemplate
bandwidth = int(bandwidth)
compress_reflections = bool(compress_reflections)
leaf_duration = durationtools.Duration(leaf_duration)
length = int(length)
pitches = [pitchtools.NamedPitch(x) for x in pitches]
staff_count = int(staff_count)
assert 0 < bandwidth
assert 0 < leaf_duration
assert 0 < length
assert 0 < len(pitches)
assert 0 < staff_count
score_template = WindungenScoreTemplate(staff_count=staff_count)
score = score_template()
all_pitches = sequencetools.repeat_sequence_to_length(length)
matrix = make_cyclic_matrix_for_rotation_by_bandwidth()
def _contents_duration(self):
if self.is_simultaneous:
return max([durationtools.Duration(0)] +
[x._preprolated_duration for x in self])
else:
duration = durationtools.Duration(0)
for x in self:
duration += x._preprolated_duration
return duration
def _duration_in_seconds(self):
from abjad.tools import scoretools
if self.is_simultaneous:
return max([durationtools.Duration(0)] +
[x._get_duration(in_seconds=True) for x in self])
else:
duration = durationtools.Duration(0)
for leaf in iterate(self).by_class(scoretools.Leaf):
duration += leaf._get_duration(in_seconds=True)
return duration
def __init__(
self,
duration=durationtools.Duration(1, 4),
parts=Exact,
):
self._duration = durationtools.Duration(duration)
if not isinstance(parts, collections.Sequence):
parts = (parts, )
assert all(_ in (None, Exact, More, Less) for _ in parts)
self._parts = parts
def _remove_and_shrink_durated_parent_containers(self):
from abjad.tools import indicatortools
from abjad.tools import scoretools
prolated_leaf_duration = self._get_duration()
parentage = self._get_parentage(include_self=False)
prolations = parentage._prolations
current_prolation, i = durationtools.Duration(1), 0
parent = self._parent
while parent is not None and not parent.is_simultaneous:
current_prolation *= prolations[i]
if isinstance(parent, scoretools.FixedDurationTuplet):
candidate_new_parent_dur = (
parent.target_duration -
current_prolation * self.written_duration)
if durationtools.Duration(0) < candidate_new_parent_dur:
parent.target_duration = candidate_new_parent_dur
elif isinstance(parent, scoretools.Measure):
indicator = parent._get_indicator(indicatortools.TimeSignature)
parent_time_signature = indicator
old_prolation = parent_time_signature.implied_prolation
naive_time_signature = (parent_time_signature.duration -
prolated_leaf_duration)
better_time_signature = mathtools.NonreducedFraction(
naive_time_signature)
better_time_signature = better_time_signature.with_denominator(
parent_time_signature.denominator)
better_time_signature = indicatortools.TimeSignature(
better_time_signature)
detach(indicatortools.TimeSignature, parent)
attach(better_time_signature, parent)
indicator = parent._get_indicator(indicatortools.TimeSignature)
parent_time_signature = indicator
new_prolation = parent_time_signature.implied_prolation
adjusted_prolation = old_prolation / new_prolation
for x in parent:
if isinstance(x, scoretools.FixedDurationTuplet):
x.target_duration *= adjusted_prolation
else:
if adjusted_prolation != 1:
new_target = \
x._preprolated_duration * adjusted_prolation
scoretools.FixedDurationTuplet(new_target, [x])
parent = parent._parent
i += 1
parentage = self._get_parentage(include_self=False)
parent = self._parent
if parent:
index = parent.index(self)
del (parent[index])
for x in parentage:
if not len(x):
x._extract()
else:
break
def make_score(self):
r'''Make MIDI playback score from scale:
::
>>> scale = tonalanalysistools.Scale('E', 'major')
>>> score = scale.make_score()
.. doctest::
>>> print(format(score))
\new Score \with {
tempoWholesPerMinute = #(ly:make-moment 30 1)
} <<
\new Staff {
\key e \major
e'8
fs'8
gs'8
a'8
b'8
cs''8
ds''8
e''8
ds''8
cs''8
b'8
a'8
gs'8
fs'8
e'4
}
>>
::
>>> show(score) # doctest: +SKIP
Returns score.
'''
ascending_notes = self.make_notes(8, durationtools.Duration(1, 8))
descending_notes = copy.deepcopy(ascending_notes[:-1])
descending_notes = list(descending_notes)
descending_notes.reverse()
descending_notes = selectiontools.Selection(descending_notes)
notes = ascending_notes + descending_notes
notes[-1].written_duration = durationtools.Duration(1, 4)
staff = scoretools.Staff(notes)
key_signature = copy.copy(self.key_signature)
attach(key_signature, staff)
score = scoretools.Score([staff])
set_(score).tempo_wholes_per_minute = schemetools.SchemeMoment(30)
return score
def _make_music(self, divisions, seeds):
#assert not seeds, repr(seeds)
if seeds is None:
seeds = 0
selections = []
divisions = [durationtools.Division(_) for _ in divisions]
denominators = datastructuretools.CyclicTuple(self.denominators)
extra_counts_per_division = self.extra_counts_per_division or (0,)
extra_counts_per_division = datastructuretools.CyclicTuple(
extra_counts_per_division
)
for i, division in enumerate(divisions, seeds):
# not yet extended to work with non-power-of-two divisions
assert mathtools.is_positive_integer_power_of_two(
division.denominator), repr(division)
denominator = denominators[i]
extra_count = extra_counts_per_division[i]
basic_duration = durationtools.Duration(1, denominator)
unprolated_note_count = None
if division < 2 * basic_duration:
notes = scoretools.make_notes([0], [division])
else:
unprolated_note_count = division / basic_duration
unprolated_note_count = int(unprolated_note_count)
unprolated_note_count = unprolated_note_count or 1
if 0 < extra_count:
modulus = unprolated_note_count
extra_count = extra_count % modulus
elif extra_count < 0:
modulus = int(math.ceil(unprolated_note_count / 2.0))
extra_count = abs(extra_count) % modulus
extra_count *= -1
note_count = unprolated_note_count + extra_count
durations = note_count * [basic_duration]
notes = scoretools.make_notes([0], durations)
assert all(
_.written_duration.denominator == denominator
for _ in notes
)
tuplet_duration = durationtools.Duration(division)
tuplet = scoretools.FixedDurationTuplet(
duration=tuplet_duration,
music=notes,
)
if unprolated_note_count is not None:
preferred_denominator = unprolated_note_count
tuplet.preferred_denominator = preferred_denominator
selection = selectiontools.Selection(tuplet)
selections.append(selection)
self._apply_beam_specifier(selections)
return selections
def make_multiplied_quarter_notes(
pitches,
multiplied_durations,
):
r'''Make quarter notes with `pitches` and `multiplied_durations`:
::
>>> args = [[0, 2, 4, 5], [(1, 4), (1, 5), (1, 6), (1, 7)]]
>>> scoretools.make_multiplied_quarter_notes(*args)
Selection(Note("c'4 * 1"), Note("d'4 * 4/5"), Note("e'4 * 2/3"), Note("f'4 * 4/7"))
Read `pitches` cyclically where the length of `pitches` is
less than the length of `multiplied_durations`:
::
>>> args = [[0], [(1, 4), (1, 5), (1, 6), (1, 7)]]
>>> scoretools.make_multiplied_quarter_notes(*args)
Selection(Note("c'4 * 1"), Note("c'4 * 4/5"), Note("c'4 * 2/3"), Note("c'4 * 4/7"))
Read `multiplied_durations` cyclically where the length of
`multiplied_durations` is less than the length of `pitches`:
::
>>> args = [[0, 2, 4, 5], [(1, 5)]]
>>> scoretools.make_multiplied_quarter_notes(*args)
Selection(Note("c'4 * 4/5"), Note("d'4 * 4/5"), Note("e'4 * 4/5"),
Note("f'4 * 4/5"))
Returns list of zero or more newly constructed notes.
'''
from abjad.tools import scoretools
multiplied_durations = [
durationtools.Duration(x) for x in multiplied_durations
]
quarter_notes = []
sequences = [pitches, multiplied_durations]
for pitch, duration in sequencetools.zip_sequences(sequences, cyclic=True):
quarter_note = scoretools.Note(pitch, durationtools.Duration(1, 4))
duration = durationtools.Duration(duration)
multiplier = durationtools.Multiplier(duration /
durationtools.Duration(1, 4))
attach(multiplier, quarter_note)
quarter_notes.append(quarter_note)
quarter_notes = selectiontools.Selection(quarter_notes)
return quarter_notes
def set_line_breaks_by_line_duration(
expr,
line_duration,
line_break_class=None,
kind='prolated',
add_empty_bars=False,
):
r'''Iterate `line_break_class` instances in `expr`
and accumulate `kind` duration.
Add line break after every total less than or equal to `line_duration`.
Set `line_break_class` to measure when `line_break_class` is none.
'''
if line_break_class is None:
line_break_class = scoretools.Measure
previous = None
cumulative_duration = durationtools.Duration(0)
for current in iterate(expr).by_class(line_break_class):
# TODO: compress these 4 lines to only the 4th line
# after duration migration
if kind == 'seconds':
current_duration = current._get_duration(in_seconds=True)
elif kind == 'prolated':
current_duration = current._get_duration()
elif kind == 'preprolated':
current_duration = current._preprolated_duration
else:
current_duration = getattr(current._get_duration(), kind)
candidate_duration = cumulative_duration + current_duration
if candidate_duration < line_duration:
cumulative_duration += current_duration
elif candidate_duration == line_duration:
command = indicatortools.LilyPondCommand('break', 'closing')
attach(command, current)
if add_empty_bars:
if current.bar_line.kind is None:
current.bar_line.kind = ''
cumulative_duration = durationtools.Duration(0)
else:
if previous is not None:
command = indicatortools.LilyPondCommand('break', 'closing')
attach(command, previous)
if add_empty_bars:
if current.bar_line.kind is None:
current.bar_line.kind = ''
cumulative_duration = current_duration
previous = current
def t_DURATION(self, t):
r'-?[1-9]\d*(/[1-9]\d*)?'
parts = t.value.partition('/')
if not parts[2]:
t.value = durationtools.Duration(int(parts[0]))
else:
numerator, denominator = int(parts[0]), int(parts[2])
fraction = mathtools.NonreducedFraction(numerator, denominator)
preprolated_duration = durationtools.Duration(fraction)
if fraction.numerator == preprolated_duration.numerator:
t.value = preprolated_duration
else:
t.value = fraction
return t
def _get_timespan(self, in_seconds=False):
from abjad.tools import durationtools
if len(self):
start_offset = \
self[0]._get_timespan(in_seconds=in_seconds)._start_offset
stop_offset = \
self[-1]._get_timespan(in_seconds=in_seconds)._stop_offset
else:
start_offset = durationtools.Duration(0)
stop_offset = durationtools.Duration(0)
return timespantools.Timespan(
start_offset=start_offset,
stop_offset=stop_offset,
)
def __init__(self, *args, **kwargs):
if len(args) == 1 and durationtools.Duration.is_token(args[0]):
args = durationtools.Duration(args[0])
elif len(args) == 1 and isinstance(args[0], type(self)):
args = args[0].duration
elif len(args) == 2 and \
isinstance(args[0], int) and isinstance(args[1], int):
args = durationtools.Duration(args)
elif len(args) == 0:
args = durationtools.Duration((1, 4))
else:
message = 'can not intialize {}: {!r}.'
message = message.format(type(self).__name__, args)
raise TypeError(message)
Scheme.__init__(self, args, **kwargs)
def test_systemtools_StorageFormatAgent_get_import_statements_04():
subject = rhythmmakertools.IncisedRhythmMaker(
incise_specifier=rhythmmakertools.InciseSpecifier(
prefix_talea=(1, ),
prefix_counts=(0, ),
suffix_talea=(1, ),
suffix_counts=(1, ),
talea_denominator=16,
body_ratio=mathtools.Ratio((1, )),
outer_divisions_only=True,
),
beam_specifier=rhythmmakertools.BeamSpecifier(
beam_each_division=False,
beam_divisions_together=False,
),
duration_spelling_specifier=rhythmmakertools.DurationSpellingSpecifier(
decrease_durations_monotonically=True,
forbidden_written_duration=durationtools.Duration(1, 2),
),
tuplet_spelling_specifier=rhythmmakertools.TupletSpellingSpecifier(
avoid_dots=True,
is_diminution=True,
simplify_redundant_tuplets=True,
),
)
agent = systemtools.StorageFormatAgent(subject)
assert agent.get_import_statements() == (
'from abjad.tools import durationtools',
'from abjad.tools import mathtools',
'from abjad.tools import rhythmmakertools',
)
def written_duration(self, expr):
rational = durationtools.Duration(expr)
if not rational.is_assignable:
message = 'not assignable duration: {!r}.'
message = message.format(rational)
raise AssignabilityError(message)
self._written_duration = rational
def implied_prolation(self):
'''Gets implied prolation of time signature.
.. container:: example
**Example 1.** Implied prolation of time signature with
power-of-two denominator:
::
>>> TimeSignature((3, 8)).implied_prolation
Multiplier(1, 1)
.. container:: example
**Example 2.** Implied prolation of time signature
with non-power-of-two denominator:
::
>>> TimeSignature((7, 12)).implied_prolation
Multiplier(2, 3)
Returns multiplier.
'''
dummy_duration = durationtools.Duration(1, self.denominator)
return dummy_duration.implied_prolation
def _make_container(self, division):
from abjad.tools import rhythmmakertools
duration_spelling_specifier = self.duration_spelling_specifier
if duration_spelling_specifier is None:
duration_spelling_specifier = \
rhythmmakertools.DurationSpellingSpecifier()
forbidden_written_duration = \
duration_spelling_specifier.forbidden_written_duration
time_signature = indicatortools.TimeSignature(division)
implied_prolation = time_signature.implied_prolation
numerator, denominator = division.pair
denominator = mathtools.greatest_power_of_two_less_equal(denominator)
assert mathtools.is_positive_integer_power_of_two(denominator)
exponent = self.exponent or 0
denominator_multiplier = 2**exponent
denominator *= denominator_multiplier
unit_duration = durationtools.Duration(1, denominator)
if forbidden_written_duration is not None:
multiplier = 1
while forbidden_written_duration <= unit_duration:
unit_duration /= 2
multiplier *= 2
numerator *= multiplier
numerator *= denominator_multiplier
notes = scoretools.make_notes(numerator * [0], [unit_duration])
if implied_prolation == 1:
result = scoretools.Container(notes)
else:
multiplier = implied_prolation
result = scoretools.Tuplet(multiplier, notes)
return result
def _split_at_measure_boundaries(
selections,
meters,
use_messiaen_style_ties=False,
):
from abjad.tools import metertools
from abjad.tools import scoretools
from abjad.tools import sequencetools
from abjad.tools.topleveltools import inspect_
from abjad.tools.topleveltools import mutate
meters = [metertools.Meter(_) for _ in meters]
durations = [durationtools.Duration(_) for _ in meters]
music = sequencetools.flatten_sequence(selections)
assert isinstance(music, list), repr(music)
total_duration = sum(durations)
music_duration = sum(inspect_(_).get_duration() for _ in music)
assert total_duration == music_duration
voice = scoretools.Voice(music)
mutate(voice[:]).split(
durations=durations,
tie_split_notes=True,
use_messiaen_style_ties=use_messiaen_style_ties,
)
selections = list(voice[:])
return selections
def _rewrite_meter_(
selections,
meters,
reference_meters=None,
rewrite_tuplets=False,
use_messiaen_style_ties=False,
):
from abjad.tools import metertools
from abjad.tools import scoretools
from abjad.tools.topleveltools import mutate
meters = [metertools.Meter(_) for _ in meters]
durations = [durationtools.Duration(_) for _ in meters]
reference_meters = reference_meters or ()
selections = DurationSpellingSpecifier._split_at_measure_boundaries(
selections,
meters,
use_messiaen_style_ties=use_messiaen_style_ties,
)
measures = scoretools.make_spacer_skip_measures(durations)
staff = scoretools.Staff(measures)
mutate(staff).replace_measure_contents(selections)
for measure, meter in zip(staff, meters):
for reference_meter in reference_meters:
if str(reference_meter) == str(meter):
meter = reference_meter
break
mutate(measure[:]).rewrite_meter(
meter,
rewrite_tuplets=rewrite_tuplets,
use_messiaen_style_ties=use_messiaen_style_ties,
)
selections = []
for measure in staff:
selections.append(measure[:])
return selections
def __init__(
self,
decrease_durations_monotonically=True,
forbid_meter_rewriting=None,
forbidden_written_duration=None,
rewrite_meter=None,
spell_metrically=None,
):
from abjad.tools import rhythmmakertools
assert isinstance(decrease_durations_monotonically, bool)
if forbidden_written_duration is not None:
forbidden_written_duration = durationtools.Duration(
forbidden_written_duration)
self._decrease_durations_monotonically = \
decrease_durations_monotonically
self._forbidden_written_duration = forbidden_written_duration
assert isinstance(rewrite_meter, (bool, type(None)))
self._rewrite_meter = rewrite_meter
assert (spell_metrically is None or isinstance(spell_metrically, bool)
or spell_metrically == 'unassignable' or isinstance(
spell_metrically, rhythmmakertools.PartitionTable))
self._spell_metrically = spell_metrically
if forbid_meter_rewriting is not None:
forbid_meter_rewriting = bool(forbid_meter_rewriting)
self._forbid_meter_rewriting = forbid_meter_rewriting
def __init__(
self,
compound_meter_multiplier=durationtools.Multiplier(1),
cyclic=True,
durations=(),
pattern_rotation_index=0,
remainder=Right,
remainder_fuse_threshold=None,
):
compound_meter_multiplier = durationtools.Multiplier(
compound_meter_multiplier)
self._compound_meter_multiplier = compound_meter_multiplier
assert isinstance(cyclic, bool), repr(cyclic)
self._cyclic = cyclic
durations = durations or ()
pattern_ = []
for division in durations:
division = mathtools.NonreducedFraction(division)
pattern_.append(division)
durations = tuple(pattern_)
self._pattern = durations
assert remainder in (Left, Right), repr(remainder)
self._remainder = remainder
assert isinstance(pattern_rotation_index, int)
self._pattern_rotation_index = pattern_rotation_index
if remainder_fuse_threshold is not None:
remainder_fuse_threshold = durationtools.Duration(
remainder_fuse_threshold, )
self._remainder_fuse_threshold = remainder_fuse_threshold
self._callbacks = ()
def _make_numeric_map_part(
self,
numerator,
prefix,
suffix,
is_note_filled=True,
):
prefix_weight = mathtools.weight(prefix)
suffix_weight = mathtools.weight(suffix)
middle = numerator - prefix_weight - suffix_weight
if numerator < prefix_weight:
weights = [numerator]
prefix = sequencetools.split_sequence(prefix,
weights,
cyclic=False,
overhang=False)[0]
middle = self._make_middle_of_numeric_map_part(middle)
suffix_space = numerator - prefix_weight
if suffix_space <= 0:
suffix = ()
elif suffix_space < suffix_weight:
weights = [suffix_space]
suffix = sequencetools.split_sequence(
suffix,
weights,
cyclic=False,
overhang=False,
)[0]
numeric_map_part = prefix + middle + suffix
return [durationtools.Duration(x) for x in numeric_map_part]
def __init__(
self,
durations=None,
include_long_duration_notes=False,
include_long_duration_rests=False,
isolated_nib_direction=None,
use_stemlets=False,
vertical_direction=None,
):
Spanner.__init__(
self,
)
if durations:
durations = tuple(durationtools.Duration(x) for x in durations)
self._durations = durations
self._include_long_duration_notes = bool(include_long_duration_notes)
self._include_long_duration_rests = bool(include_long_duration_rests)
assert isolated_nib_direction in (Left, Right, None)
self._isolated_nib_direction = isolated_nib_direction
if self._durations is not None:
self._span_points = mathtools.cumulative_sums(self.durations)[1:]
else:
self._span_points = [self._get_duration()]
self._use_stemlets = bool(use_stemlets)
assert vertical_direction in (Up, Down, Center, None)
self._vertical_direction = vertical_direction
