class GenerateTwoPartFifthSpecies:
    def __init__(self,
                 length: int = None,
                 mode: ModeOption = None,
                 range_option: RangeOption = None):
        self._mode = mode or ModeOption.AEOLIAN
        self._length = length or 8 + math.floor(
            random() * 5)  #todo: replace with normal distribution
        self._range = range_option if range_option is not None else RangeOption.ALTO
        self._mr = ModeResolver(self._mode, range_option=self._range)
        self._melodic_insertion_checks = [
            self._handles_adjacents,
            self._handles_interval_order,
            self._handles_nearby_augs_and_dims,
            self._handles_nearby_leading_tones,
            self._handles_ascending_minor_sixth,
            self._handles_ascending_quarter_leaps,
            self._handles_descending_quarter_leaps,
            self._handles_repetition,
            self._handles_eigths,
            self._handles_highest,
            self._handles_resolution_of_anticipation,
            self._handles_repeated_two_notes,
            self._handles_quarter_between_two_leaps,
            self._handles_upper_neighbor,
            self._handles_antipenultimate_bar,
        ]
        self._harmonic_insertion_checks = [
            self._filters_dissonance_on_downbeat, self._resolves_suspension,
            self._prepares_weak_quarter_dissonance,
            self._resolves_weak_quarter_dissonance,
            self._resolves_cambiata_tail, self._prepares_weak_half_note,
            self._resolves_dissonant_quarter_on_weak_half_note,
            self._resolves_passing_half_note, self._handles_hiddens,
            self._handles_parallels, self._handles_doubled_leading_tone
        ]
        self._melodic_rhythm_filters = [
            self._handles_runs, self._handles_consecutive_quarters,
            self._handles_penultimate_bar, self._handles_first_eighth,
            self._handles_sharp_durations, self._handles_whole_note_quota,
            self._handles_repeated_note,
            self._handles_rhythm_after_descending_quarter_leap,
            self._handles_dotted_whole_after_quarters,
            self._handles_repeated_dotted_halfs,
            self._handles_antipenultimate_rhythm,
            self._handles_half_note_chain, self._handles_missing_syncopation,
            self._handles_quarters_after_whole,
            self._handles_repetition_on_consecutive_syncopated_measures
        ]
        self._harmonic_rhythm_filters = [
            self._prepares_suspension,
            self._resolves_cambiata,
            self._handles_weak_half_note_dissonance,
        ]
        self._index_checks = [self._highest_and_lowest_placed]
        self._change_params = [
            self._check_for_highest_and_lowest,
            self._check_for_on_beat_whole_note,
            # self._check_if_new_run_is_added,
            self._check_if_eighths_are_added
        ]
        self._final_checks = [
            # self._parameters_are_correct,
            self._has_only_one_octave,
            self._no_unresolved_leading_tones
        ]
        self._params = [
            "highest_has_been_placed", "lowest_has_been_placed",
            "num_on_beat_whole_notes_placed", "eighths_have_been_placed"
        ]
        gcf = GenerateCantusFirmus(self._length, self._mode, 4)
        cf = None
        #limit ourselves to Cantus Firmuses that end with a descending step to allow for easier cadences
        while cf is None or cf.get_note(self._length -
                                        2).get_scale_degree_interval(
                                            cf.get_note(self._length -
                                                        1)) != -2:
            cf = gcf.generate_cf()
        self._cantus_object = cf
        self._cantus = cf.get_notes()

    def print_counterpoint(self):
        print("  FIFTH SPECIES:")
        for i in range(self._length):
            for j in range(4):
                cf_note = str(
                    self._cantus[i]) if j == 0 else "                   "
                cntpt_note = str(self._counterpoint_obj[(i, j)]) if (
                    i, j) in self._counterpoint_obj else ""
                if cntpt_note is None: cntpt_note = "None"
                if (i, j + 0.5) in self._counterpoint_obj:
                    cntpt_note += "  " + str(
                        self._counterpoint_obj[(i, j + 0.5)])
                show_index = "    "
                if j == 0:
                    show_index = str(i) + ":  " if i < 10 else str(i) + ": "
                print(show_index + "  " + cf_note + "  " + str(cntpt_note))

    def get_optimal(self):
        if len(self._solutions) == 0:
            return None
        optimal = self._solutions[0]
        self._map_solution_onto_counterpoint_dict(optimal)
        self.print_counterpoint()
        return [optimal, self._cantus]

    def generate_2p5s(self):
        print("MODE = ", self._mode.value["name"])
        self._solutions = []

        def attempt():
            self._num_backtracks = 0
            self._solutions_this_attempt = 0
            initialized = self._initialize()
            self._backtrack()

        attempts = 0
        while len(self._solutions) < 100 and attempts < 1:
            print("attempt", attempts)
            attempt()
            attempts += 1
        print("number of attempts:", attempts)
        print("number of solutions:", len(self._solutions))
        if len(self._solutions) > 0:
            shuffle(self._solutions)
            self._solutions.sort(key=lambda sol: self._score_solution(sol))

    def _initialize(self) -> bool:
        indices = []
        for i in range(self._length - 1):
            indices += [(i, 0), (i, 1), (i, 1.5), (i, 2), (i, 3)]
        indices += [(self._length - 1, 0)]
        self._all_indices = indices[:]
        self._remaining_indices = indices[:]
        self._remaining_indices.reverse()
        print(self._all_indices)
        #initialize counterpoint data structure, that will map indices to notes
        self._counterpoint_obj = {}
        for index in self._all_indices:
            self._counterpoint_obj[index] = None
        #also initialize counterpoint data structure as list
        self._counterpoint_lst = []
        #initialize parameters for this attempt
        self._attempt_params = {
            "lowest": None,
            "highest": None,
            "highest_must_appear_by": None,
            "lowest_must_appear_by": None,
            "highest_has_been_placed": False,
            "lowest_has_been_placed": False,
            "max_on_beat_whole_notes": None,
            "num_on_beat_whole_notes_placed": 0,
            "eighths_have_been_placed": False,
            "run_indices": set()
        }
        vocal_range = randint(8, 10)
        self._attempt_params[
            "lowest"] = self._mr.get_default_note_from_interval(
                self._mr.get_lowest(), randint(1, 13 - vocal_range))
        self._attempt_params[
            "highest"] = self._mr.get_default_note_from_interval(
                self._attempt_params["lowest"], vocal_range)
        self._attempt_params["highest_must_appear_by"] = randint(
            3, self._length - 1)
        self._attempt_params["lowest_must_appear_by"] = randint(
            3 if self._attempt_params["highest_must_appear_by"] >= 5 else 5,
            self._length - 1)
        self._attempt_params["max_on_beat_whole_notes"] = randint(1, 2)

        self._place_runs()

        self._store_params = []
        self._stored_indices = []
        self._valid_pitches = [
            self._attempt_params["lowest"], self._attempt_params["highest"]
        ]  #order is unimportant
        for i in range(2, vocal_range):
            self._valid_pitches += self._mr.get_notes_from_interval(
                self._attempt_params["lowest"], i)

        return True

    def _place_runs(self) -> None:
        runs = [randint(5, 11)]
        if self._length > 8: runs.append(4)
        shuffle(runs)
        start_beats = []
        for run in runs:
            pos = randint(3, (self._length - 2) * 4 - run)
            while pos % 4 == 0:
                pos = randint(3, (self._length - 2) * 4 - run)
            start_beats.append(pos)
        if len(runs) == 2 and start_beats[0] + runs[0] + 12 >= start_beats[1]:
            start_beats.pop()
            runs.pop()
        for i in range(len(runs)):
            for j in range(runs[i]):
                total_beats = start_beats[i] + j
                index = (total_beats // 4, total_beats % 4)
                self._attempt_params["run_indices"].add(index)

    def _backtrack(self) -> None:
        if (self._num_backtracks >
                100000) or (self._solutions_this_attempt == 0
                            and self._num_backtracks > 10000):
            return
        self._num_backtracks += 1
        if self._num_backtracks % 10000 == 0:
            print("backtrack number:", self._num_backtracks)
        if len(self._remaining_indices) == 0:
            if self._passes_final_checks():
                if self._solutions_this_attempt == 0:
                    print("FOUND SOLUTION!")
                self._solutions.append(self._counterpoint_lst[:])
                self._solutions_this_attempt += 1
            return
        (bar, beat) = self._remaining_indices.pop()
        if self._passes_index_checks((bar, beat)):
            candidates = list(
                filter(lambda n: self._passes_insertion_checks(n, (bar, beat)),
                       self._valid_pitches))
            shuffle(candidates)
            if bar == 0 and beat == 0:
                candidates.append(Note(1, 0, 4, accidental=ScaleOption.REST))
            # print("candidates for index", bar, beat, ": ", len(candidates))
            notes_to_insert = []
            for candidate in candidates:
                durations = self._get_valid_durations(candidate, (bar, beat))
                for dur in durations:
                    notes_to_insert.append(
                        Note(candidate.get_scale_degree(),
                             candidate.get_octave(),
                             dur,
                             accidental=candidate.get_accidental()))
            shuffle(notes_to_insert)
            for note_to_insert in notes_to_insert:
                self._insert_note(note_to_insert, (bar, beat))
                self._backtrack()
                self._remove_note(note_to_insert, (bar, beat))
        self._remaining_indices.append((bar, beat))

    def _passes_index_checks(self, index: tuple) -> bool:
        for check in self._index_checks:
            if not check(index): return False
        return True

    def _passes_insertion_checks(self, note: Note, index: tuple) -> bool:
        (bar, beat) = index
        if bar == 0 and (beat == 0 or
                         (beat == 2
                          and self._counterpoint_lst[0].get_accidental()
                          == ScaleOption.REST)):
            return self._check_starting_pitch(note)
        if bar == self._length - 1:
            if not self._check_last_pitch(note): return False
        for check in self._melodic_insertion_checks:
            if not check(note, (bar, beat)):
                # print("failed insertion check:", str(note), index, "on function", check.__name__)
                return False
        # print("passed insertion checks!", str(note), index)
        for check in self._harmonic_insertion_checks:
            if not check(note, (bar, beat)):
                # print("failed insertion check:", str(note), index, "on function", check.__name__)
                return False
        return True

    def _get_valid_durations(self, note: Note, index: tuple) -> set:
        (bar, beat) = index
        if bar == self._length - 1: return {16}
        if note.get_accidental() == ScaleOption.REST: return {4}
        if bar == 0 and beat == 0: return self._get_first_beat_options(note)
        durs = self._get_durations_from_beat(index)
        prev_length = len(durs)
        for check in self._melodic_rhythm_filters:
            durs = check(note, index, durs)
            if len(durs) == 0: break
        for check in self._harmonic_rhythm_filters:
            durs = check(note, index, durs)
            if len(durs) == 0: break
        return durs

    def _insert_note(self, note: Note, index: tuple) -> set:
        self._counterpoint_lst.append(note)
        self._counterpoint_obj[index] = note
        self._store_params.append({})
        for param in self._params:
            self._store_params[-1][param] = self._attempt_params[param]
        self._bury_indices(note, index)
        for check in self._change_params:
            check(note, index)

    def _remove_note(self, note: Note, index: tuple) -> set:
        self._counterpoint_lst.pop()
        self._counterpoint_obj[index] = None
        for param in self._params:
            self._attempt_params[param] = self._store_params[-1][param]
        self._store_params.pop()
        self._unbury_indices(note, index)

    def _passes_final_checks(self) -> bool:
        for check in self._final_checks:
            if not check():
                # print("failed final check:", check.__name__)
                return False
        return True

    ######################################
    ### melodic insertion checks #########

    def _check_starting_pitch(self, note: Note) -> bool:
        if note.get_accidental() == ScaleOption.REST:
            return True
        if self._cantus[0].get_scale_degree_interval(note) not in [
                -8, 1, 5, 8
        ]:
            return False
        return note.get_accidental() == ScaleOption.NATURAL

    def _check_last_pitch(self, note: Note) -> bool:
        if self._mr.get_final() != note.get_scale_degree(
        ) or note.get_accidental() != ScaleOption.NATURAL:
            return False
        if self._counterpoint_lst[-1].get_scale_degree_interval(note) == 2:
            return self._mr.is_unison(self._mr.get_leading_tone_of_note(note),
                                      self._counterpoint_lst[-1])
        if self._counterpoint_lst[-1] != -2: return False
        return self._mr.is_unison(self._counterpoint_lst[-1],
                                  self._mr.get_leading_tone_of_note(note))

    def _handles_adjacents(self, note: Note, index: tuple) -> bool:
        (bar, beat) = index
        (sdg_interval,
         chro_interval) = self._mr.get_intervals(self._counterpoint_lst[-1],
                                                 note)
        if sdg_interval not in LegalIntervalsFifthSpecies[
                "adjacent_melodic_scalar"]:
            return False
        if chro_interval not in LegalIntervalsFifthSpecies[
                "adjacent_melodic_chromatic"]:
            return False
        if (sdg_interval, chro_interval
            ) in LegalIntervalsFifthSpecies["forbidden_combinations"]:
            return False
        return True

    def _handles_interval_order(self, note: Note, index: tuple) -> bool:
        potential_interval = self._counterpoint_lst[
            -1].get_scale_degree_interval(note)
        if potential_interval >= 3:
            for i in range(len(self._counterpoint_lst) - 2, -1, -1):
                interval = self._counterpoint_lst[i].get_scale_degree_interval(
                    self._counterpoint_lst[i + 1])
                if interval < 0: return True
                if interval > 2: return False
        if potential_interval == 2:
            segment_has_leap = False
            for i in range(len(self._counterpoint_lst) - 2, -1, -1):
                interval = self._counterpoint_lst[i].get_scale_degree_interval(
                    self._counterpoint_lst[i + 1])
                if interval < 0: return True
                if segment_has_leap: return False
                segment_has_leap = interval > 2
        if potential_interval == -2:
            segment_has_leap = False
            for i in range(len(self._counterpoint_lst) - 2, -1, -1):
                interval = self._counterpoint_lst[i].get_scale_degree_interval(
                    self._counterpoint_lst[i + 1])
                if interval > 0: return True
                if segment_has_leap or interval == -8: return False
                segment_has_leap = interval < -2
        if potential_interval <= -3:
            for i in range(len(self._counterpoint_lst) - 2, -1, -1):
                interval = self._counterpoint_lst[i].get_scale_degree_interval(
                    self._counterpoint_lst[i + 1])
                if interval > 0: return True
                if interval < -2: return False
        return True

    def _handles_nearby_augs_and_dims(self, note: Note, index: tuple) -> bool:
        if len(self._counterpoint_lst) < 2: return True
        if self._mr.is_cross_relation(
                note, self._counterpoint_lst[-2]
        ) and self._counterpoint_lst[-1].get_duration() <= 2:
            return False
        if self._counterpoint_lst[-2].get_duration(
        ) != 2 and self._counterpoint_lst[-1].get_duration() != 2:
            return True
        (sdg_interval,
         chro_interval) = self._mr.get_intervals(self._counterpoint_lst[-2],
                                                 note)
        return (abs(sdg_interval) != 2
                or abs(chro_interval) != 3) and (abs(sdg_interval) != 3
                                                 or abs(chro_interval) != 2)

    def _handles_nearby_leading_tones(self, note: Note, index: tuple) -> bool:
        (bar, beat) = index
        if beat == 2 and (
                bar - 1,
                2) in self._counterpoint_obj and self._counterpoint_obj[
                    (bar - 1, 2)].get_duration() > 4:
            if self._mr.is_sharp(self._counterpoint_obj[(
                    bar - 1, 2)]) and self._counterpoint_obj[
                        (bar - 1, 2)].get_chromatic_interval(note) != 1:
                return False
        if beat == 0 and bar != 0:
            for i, num in enumerate([0, 1, 1.5, 2, 3]):
                if (bar - 1,
                        num) in self._counterpoint_obj and self._mr.is_sharp(
                            self._counterpoint_obj[(bar - 1, num)]):
                    resolved = False
                    for j in range(i + 1, 5):
                        next_index = (bar - 1, [0, 1, 1.5, 2, 3][j])
                        if next_index in self._counterpoint_obj and self._counterpoint_obj[
                            (bar - 1, num)].get_chromatic_interval(
                                self._counterpoint_obj[next_index]) == 1:
                            resolved = True
                    if not resolved and self._counterpoint_obj[
                        (bar - 1, num)].get_chromatic_interval(note) != 1:
                        return False
        return True

    def _handles_ascending_minor_sixth(self, note: Note, index: tuple) -> bool:
        if len(self._counterpoint_lst) < 2: return True
        if self._counterpoint_lst[-2].get_chromatic_interval(
                self._counterpoint_lst[-1]) == 8:
            return self._counterpoint_lst[-1].get_chromatic_interval(
                note) == -1
        return True

    def _handles_ascending_quarter_leaps(self, note: Note,
                                         index: tuple) -> bool:
        (bar, beat) = index
        if self._counterpoint_lst[-1].get_scale_degree_interval(note) > 2:
            if beat % 2 == 1: return False
            if len(self._counterpoint_lst
                   ) >= 2 and self._counterpoint_lst[-1].get_duration() == 2:
                if self._counterpoint_lst[-2].get_scale_degree_interval(
                        self._counterpoint_lst[-1]) > 0:
                    return False
        return True

    def _handles_descending_quarter_leaps(self, note: Note,
                                          index: tuple) -> bool:
        (bar, beat) = index
        if len(self._counterpoint_lst) < 2: return True
        if self._counterpoint_lst[-2].get_scale_degree_interval(
                self._counterpoint_lst[-1]
        ) < -2 and self._counterpoint_lst[-1].get_duration() == 2:
            if self._counterpoint_lst[-1].get_scale_degree_interval(note) == 2:
                return True
            return self._counterpoint_lst[-2].get_scale_degree_interval(
                note) in [-2, 1, 2]
        return True

    def _handles_repetition(self, note: Note, index: tuple) -> bool:
        (bar, beat) = index
        if self._mr.is_unison(self._counterpoint_lst[-1], note) and (
                beat != 2 or self._counterpoint_lst[-1].get_duration() != 2):
            return False
        return True

    def _handles_eigths(self, note: Note, index: tuple) -> bool:
        (bar, beat) = index
        if beat == 1.5 and abs(self._counterpoint_lst[-1].
                               get_scale_degree_interval(note)) != 2:
            return False
        if beat != 2: return True
        if self._counterpoint_lst[-1].get_duration() != 1: return True
        first_interval = self._counterpoint_lst[-3].get_scale_degree_interval(
            self._counterpoint_lst[-2])
        second_interval = self._counterpoint_lst[-2].get_scale_degree_interval(
            self._counterpoint_lst[-1])
        third_interval = self._counterpoint_lst[-1].get_scale_degree_interval(
            note)
        if abs(third_interval) != 2 or (second_interval == 2 and third_interval
                                        == -2) or (first_interval == 2
                                                   and second_interval == -2):
            return False
        return True

    def _handles_highest(self, note: Note, index: tuple) -> bool:
        if self._attempt_params[
                "highest_has_been_placed"] and self._mr.is_unison(
                    self._attempt_params["highest"], note):
            return False
        return True

    def _handles_resolution_of_anticipation(self, note: Note,
                                            index: tuple) -> bool:
        if len(self._counterpoint_lst) < 2 or not self._mr.is_unison(
                self._counterpoint_lst[-2], self._counterpoint_lst[-1]):
            return True
        return self._counterpoint_lst[-1].get_scale_degree_interval(note) == -2

    def _handles_repeated_two_notes(self, note: Note, index: tuple) -> bool:
        (bar, beat) = index
        if len(self._counterpoint_lst) < 3: return True
        if not self._mr.is_unison(
                self._counterpoint_lst[-3],
                self._counterpoint_lst[-1]) or not self._mr.is_unison(
                    self._counterpoint_lst[-2], note):
            return True
        if self._counterpoint_lst[-1].get_scale_degree_interval(note) != 2:
            return False
        if self._counterpoint_lst[-2].get_duration() != 8 or beat != 0:
            return False
        return True

    def _handles_quarter_between_two_leaps(self, note: Note,
                                           index: tuple) -> bool:
        if self._counterpoint_lst[-1].get_duration() != 2 or len(
                self._counterpoint_lst) < 2:
            return True
        first_interval, second_interval = self._counterpoint_lst[
            -2].get_scale_degree_interval(
                self._counterpoint_lst[-1]
            ), self._counterpoint_lst[-1].get_scale_degree_interval(note)
        if abs(first_interval) == 2 or abs(second_interval) == 2:
            return True
        if first_interval > 0 and second_interval < 0: return False
        if first_interval == -8 and second_interval == 8: return False
        return True

    def _handles_upper_neighbor(self, note: Note, index: tuple) -> bool:
        (bar, beat) = index
        if (beat % 2 == 0 and self._counterpoint_lst[-1].get_duration() == 2
                and self._counterpoint_lst[-1].get_scale_degree_interval(note)
                == -2 and len(self._counterpoint_lst) >= 2
                and self._counterpoint_lst[-2].get_scale_degree_interval(
                    self._counterpoint_lst[-1]) == 2
                and self._counterpoint_lst[-2].get_duration() != 2):
            return False
        return True

    def _handles_antipenultimate_bar(self, note: Note, index: tuple) -> bool:
        if index == (self._length - 3, 2):
            if note.get_accidental(
            ) != ScaleOption.NATURAL or note.get_scale_degree(
            ) != self._mr.get_final():
                return False
        return True

    ######################################
    ###### harmonic insertion checks ######

    def _filters_dissonance_on_downbeat(self, note: Note,
                                        index: tuple) -> bool:
        (bar, beat) = index
        if beat != 0: return True
        cf_note = self._cantus[bar]
        return self._is_consonant(cf_note, note)

    def _resolves_suspension(self, note: Note, index: tuple) -> bool:
        (bar, beat) = index
        if beat not in [1, 2] or (bar, 0) in self._counterpoint_obj:
            return True
        susp_index = (bar - 1,
                      2) if (bar - 1,
                             2) in self._counterpoint_obj else (bar - 1, 0)
        cf_note, susp = self._cantus[bar], self._counterpoint_obj[susp_index]
        if cf_note.get_scale_degree_interval(
                susp) in LegalIntervalsFifthSpecies["resolvable_dissonance"]:
            return susp.get_scale_degree_interval(note) == -2
        return True

    def _prepares_weak_quarter_dissonance(self, note: Note,
                                          index: tuple) -> bool:
        (bar, beat) = index
        if beat % 2 != 1 or self._is_consonant(self._cantus[bar], note):
            return True
        if not self._is_consonant(self._cantus[bar],
                                  self._counterpoint_lst[-1]):
            return False
        return abs(
            self._counterpoint_lst[-1].get_scale_degree_interval(note)) == 2

    def _resolves_weak_quarter_dissonance(self, note: Note,
                                          index: tuple) -> bool:
        (bar, beat) = index
        if beat % 2 != 0 or self._counterpoint_lst[-1].get_duration() != 2:
            return True
        if self._is_consonant(self._cantus[bar if beat > 0 else bar - 1],
                              self._counterpoint_lst[-1]):
            return True
        first_interval = self._counterpoint_lst[-2].get_scale_degree_interval(
            self._counterpoint_lst[-1])
        second_interval = self._counterpoint_lst[-1].get_scale_degree_interval(
            note)
        if second_interval not in [-3, -2, 1]: return False
        if first_interval == 2 and second_interval == -3: return False
        return True

    def _resolves_cambiata_tail(self, note: Note, index: tuple) -> bool:
        (bar, beat) = index
        if beat == 1.5: return True
        first_index, second_index = (bar - 1, 1), (bar - 1, 2)
        if beat in [1, 2]:
            first_index, second_index = (bar - 1, 3), (bar, 0)
        if beat == 3:
            first_index, second_index = (bar, 1), (bar, 2)
        if first_index not in self._counterpoint_obj or second_index not in self._counterpoint_obj:
            return True
        cf_note = self._cantus[bar if beat == 3 else bar - 1]
        if not self._is_consonant(
                cf_note, self._counterpoint_obj[first_index]
        ) and self._counterpoint_obj[first_index].get_scale_degree_interval(
                self._counterpoint_obj[second_index]) == -3:
            return self._counterpoint_lst[-1].get_scale_degree_interval(
                note) == 2
        return True

    def _prepares_weak_half_note(self, note: Note, index: tuple) -> bool:
        (bar, beat) = index
        if beat != 2: return True
        cf_note = self._cantus[bar]
        if self._is_consonant(cf_note, note): return True
        if (bar, 0) not in self._counterpoint_obj or self._counterpoint_obj[
            (bar, 0)].get_duration() != 4:
            return False
        return abs(
            self._counterpoint_obj[(bar,
                                    0)].get_scale_degree_interval(note)) == 2

    def _resolves_dissonant_quarter_on_weak_half_note(self, note: Note,
                                                      index: tuple) -> bool:
        (bar, beat) = index
        if beat != 3 or (bar, 2) not in self._counterpoint_obj: return True
        if self._is_consonant(self._cantus[bar],
                              self._counterpoint_obj[(bar, 2)]):
            return True
        return self._counterpoint_obj[(
            bar, 2)].get_scale_degree_interval(note) == -2

    def _resolves_passing_half_note(self, note: Note, index: tuple) -> bool:
        (bar, beat) = index
        if beat != 0 or (
                bar - 1,
                2) not in self._counterpoint_obj or self._counterpoint_obj[
                    (bar - 1, 2)].get_duration() != 4:
            return True
        if self._is_consonant(self._counterpoint_obj[(bar - 1, 2)],
                              self._cantus[bar - 1]):
            return True
        return self._counterpoint_lst[-2].get_scale_degree_interval(
            self._counterpoint_lst[-1]
        ) == self._counterpoint_lst[-1].get_scale_degree_interval(note)

    def _handles_hiddens(self, note: Note, index: tuple) -> bool:
        (bar, beat) = index
        if beat != 0 or self._cantus[bar].get_chromatic_interval(note) not in [
                -19, -12, -7, 0, 7, 12, 19
        ]:
            return True
        upper_interval = self._counterpoint_lst[-1].get_scale_degree_interval(
            note)
        lower_interval = self._cantus[bar - 1].get_scale_degree_interval(
            self._cantus[bar])
        if (upper_interval > 0
                and lower_interval > 0) or (upper_interval < 0
                                            and lower_interval < 0):
            return False
        return True

    def _handles_parallels(self, note: Note, index: tuple) -> bool:
        (bar, beat) = index
        if beat == 2 and self._counterpoint_lst[-1].get_duration(
        ) >= 8 and self._cantus[bar].get_chromatic_interval(note) in [
                -19, -12, 0, 12, 19
        ]:
            return self._cantus[bar].get_chromatic_interval(
                note) != self._cantus[bar - 1].get_chromatic_interval(
                    self._counterpoint_lst[-1])
        if beat != 0 or self._cantus[bar].get_chromatic_interval(note) not in [
                -19, -12, 0, 12, 19
        ]:
            return True
        if (bar - 1, 2) in self._counterpoint_obj and self._cantus[
                bar - 1].get_chromatic_interval(self._counterpoint_obj[(
                    bar - 1,
                    2)]) == self._cantus[bar].get_chromatic_interval(note):
            return False
        index_to_check = (bar - 1, 0)
        if index_to_check not in self._counterpoint_obj or self._counterpoint_obj[
                index_to_check].get_duration() == 2:
            return True
        if self._cantus[bar - 1].get_chromatic_interval(
                self._counterpoint_obj[index_to_check]
        ) == self._cantus[bar].get_chromatic_interval(note):
            return False
        return True

    def _handles_doubled_leading_tone(self, note: Note, index: tuple) -> bool:
        (bar, beat) = index
        if beat != 0 or self._cantus[bar].get_chromatic_interval(note) not in [
                -12, 0, 12
        ]:
            return True
        if (note.get_scale_degree() + 1) % 7 == self._mr.get_final():
            return False
        return True

    ######################################
    ###### melodic rhythms filters #######

    def _handles_runs(self, note: Note, index: tuple, durs: set) -> set:
        (bar, beat) = index
        if index in self._attempt_params["run_indices"]:
            return {2} if 2 in durs else set()
        if (bar, beat + 1) in self._attempt_params["run_indices"]:
            for d in [4, 6, 8, 12]:
                durs.discard(d)
        two_beats_next = (bar, beat + 2) if beat == 0 else (bar + 1, 0)
        if two_beats_next in self._attempt_params["run_indices"]:
            for d in [2, 6, 8, 12]:
                durs.discard(d)
        three_beats_next = (bar, beat + 3) if beat == 0 else (bar + 1, 1)
        if three_beats_next in self._attempt_params["run_indices"]:
            for d in [2, 8, 12]:
                durs.discard(d)
        if (bar + 1, 2) in self._attempt_params["run_indices"]:
            durs.discard(12)
        return durs

    def _get_durations_from_beat(self, index: tuple) -> set:
        (bar, beat) = index
        if beat == 1.5: return {1}
        if beat == 3: return {2}
        if beat == 1: return {1, 2}
        if beat == 2: return {2, 4, 6, 8}
        if beat == 0: return {2, 4, 6, 8, 12} if bar == 0 else {2, 4, 6, 8}

    def _handles_consecutive_quarters(self, note: Note, index: tuple,
                                      durs: set) -> set:
        (bar, beat) = index
        if self._counterpoint_lst[-1].get_duration() != 2: return durs
        if self._counterpoint_lst[-1].get_scale_degree_interval(
                note) > 0 and beat == 2:
            durs.discard(4)
        if beat == 2 and self._counterpoint_lst[-2].get_duration(
        ) == 2 and self._counterpoint_lst[-3].get_duration() != 2:
            durs.discard(4)
        for i in range(len(self._counterpoint_lst) - 2, -1, -1):
            if self._counterpoint_lst[i].get_duration() != 2:
                return durs
            if abs(self._counterpoint_lst[i].get_scale_degree_interval(
                    self._counterpoint_lst[i + 1])) > 2:
                durs.discard(2)
                return durs

    def _handles_penultimate_bar(self, note: Note, index: tuple,
                                 durs: set) -> set:
        (bar, beat) = index
        if bar != self._length - 2: return durs
        if beat == 2:
            durs.discard(8)
            durs.discard(6)
            durs.discard(2)
        if beat == 0:
            durs.discard(12)
        return durs

    def _handles_first_eighth(self, note: Note, index: tuple,
                              durs: set) -> set:
        (bar, beat) = index
        if (beat == 1 and
                abs(self._counterpoint_lst[-1].get_scale_degree_interval(note))
                != 2) or self._attempt_params["eighths_have_been_placed"]:
            durs.discard(1)
        if beat == 2 and self._counterpoint_lst[-1].get_duration(
        ) == 1 and self._counterpoint_lst[-3].get_duration() == 2:
            durs.discard(4)
            durs.discard(8)
            durs.discard(6)
        return durs

    def _handles_sharp_durations(self, note: Note, index: tuple,
                                 durs: set) -> set:
        if self._mr.is_sharp(note): durs.discard(12)
        return durs

    def _handles_whole_note_quota(self, note: Note, index: tuple,
                                  durs: set) -> set:
        (bar, beat) = index
        if self._attempt_params[
                "num_on_beat_whole_notes_placed"] == self._attempt_params[
                    "max_on_beat_whole_notes"]:
            if beat == 0:
                durs.discard(8)
                durs.discard(12)
        return durs

    def _handles_repeated_note(self, note: Note, index: tuple,
                               durs: set) -> set:
        if self._mr.is_unison(self._counterpoint_lst[-1], note):
            durs.discard(4)
            durs.discard(2)
        return durs

    def _handles_rhythm_after_descending_quarter_leap(self, note: Note,
                                                      index: tuple,
                                                      durs: set) -> set:
        (bar, beat) = index
        if self._counterpoint_lst[-1].get_duration(
        ) == 2 and self._counterpoint_lst[-1].get_scale_degree_interval(
                note) < -2:
            durs.discard(8)
            durs.discard(12)
            durs.discard(6)
        return durs

    def _handles_dotted_whole_after_quarters(self, note: Note, index: tuple,
                                             durs: set) -> set:
        if self._counterpoint_lst[-1].get_duration() == 2: durs.discard(12)
        return durs

    def _handles_repeated_dotted_halfs(self, note: Note, index: tuple,
                                       durs: set) -> set:
        (bar, beat) = index
        if beat != 0: return durs
        if (bar - 1, 0) in self._counterpoint_obj and self._counterpoint_obj[(
                bar - 1, 0)].get_duration() == 6:
            durs.discard(6)
        if bar % 2 == 0 and (
                bar - 2,
                0) in self._counterpoint_obj and self._counterpoint_obj[(
                    bar - 2, 0)].get_duration() == 6:
            durs.discard(6)
        return durs

    def _handles_antipenultimate_rhythm(self, note: Note, index: tuple,
                                        durs: set) -> set:
        if index == (self._length - 3, 2):
            durs.discard(4)
            durs.discard(2)
        if index == (self._length - 3, 0):
            durs.discard(8)
            durs.discard(6)
        return durs

    def _handles_half_note_chain(self, note: Note, index: tuple,
                                 durs: set) -> set:
        (bar, beat) = index
        if beat == 2 and len(self._counterpoint_lst) >= 3:
            if self._counterpoint_lst[-3].get_duration(
            ) == 4 and self._counterpoint_lst[-2].get_duration(
            ) == 4 and self._counterpoint_lst[-1].get_duration() == 4:
                durs.discard(4)
        return durs

    def _handles_missing_syncopation(self, note: Note, index: tuple,
                                     durs: set) -> set:
        (bar, beat) = index
        if beat != 0 or (bar - 1, 0) not in self._counterpoint_obj or (
                bar - 2, 0) not in self._counterpoint_obj or (
                    bar - 3, 0) not in self._counterpoint_obj:
            return durs
        if self._counterpoint_obj[
            (bar - 3, 0)].get_duration() >= 4 and self._counterpoint_obj[
                (bar - 2, 0)].get_duration() >= 4 and self._counterpoint_obj[
                    (bar - 1, 0)].get_duration() >= 4:
            durs.discard(4)
            durs.discard(6)
            durs.discard(8)
        return durs

    def _handles_quarters_after_whole(self, note: Note, index: tuple,
                                      durs: set) -> set:
        (bar, beat) = index
        if beat == 0 and self._counterpoint_lst[-1].get_duration() == 8:
            durs.discard(2)
        return durs

    def _handles_repetition_on_consecutive_syncopated_measures(
            self, note: Note, index: tuple, durs: set) -> set:
        (bar, beat) = index
        if beat == 2 and (bar, 0) not in self._counterpoint_obj and (
                bar - 1, 2) in self._counterpoint_obj and self._mr.is_unison(
                    self._counterpoint_obj[(bar - 1, 2)], note):
            durs.discard(6)
            durs.discard(8)
        return durs

    ##########################################
    ###### harmonic rhythm filters ###########

    def _get_first_beat_options(self, note: Note) -> set:
        durs = {4, 6, 8, 12}
        if not self._is_consonant(
                self._cantus[1],
                note) and self._cantus[1].get_scale_degree_interval(
                    note
                ) not in LegalIntervalsFifthSpecies["resolvable_dissonance"]:
            durs.discard(12)
        return durs

    def _prepares_suspension(self, note: Note, index: tuple, durs: set) -> set:
        (bar, beat) = index
        if bar == self._length - 1 or self._is_consonant(
                self._cantus[bar + 1], note):
            return durs
        if self._cantus[bar + 1].get_scale_degree_interval(
                note) in LegalIntervalsFifthSpecies["resolvable_dissonance"]:
            return durs
        if beat == 0:
            durs.discard(12)
        if beat == 2:
            durs.discard(8)
            durs.discard(6)
        return durs

    def _resolves_cambiata(self, note: Note, index: tuple, durs: set) -> set:
        (bar, beat) = index
        if beat % 2 != 0: return durs
        index_to_check = (bar - 1, 3) if beat == 0 else (bar, 1)
        if index_to_check not in self._counterpoint_obj: return durs
        if self._is_consonant(self._cantus[bar - 1 if beat == 0 else bar],
                              self._counterpoint_obj[index_to_check]):
            return durs
        if self._counterpoint_obj[index_to_check].get_scale_degree_interval(
                note) != -3:
            return durs
        durs.discard(12)
        durs.discard(8)
        durs.discard(6)
        return durs

    def _handles_weak_half_note_dissonance(self, note: Note, index: tuple,
                                           durs: set) -> set:
        (bar, beat) = index
        if beat != 2 or self._is_consonant(self._cantus[bar], note):
            return durs
        durs.discard(6)
        durs.discard(8)
        if self._counterpoint_lst[-1].get_scale_degree_interval(note) == 2:
            durs.discard(2)
        return durs

    ##########################################
    ########### index checks #################

    def _highest_and_lowest_placed(self, index: tuple) -> bool:
        (bar, beat) = index
        if bar >= self._attempt_params[
                "highest_must_appear_by"] and not self._attempt_params[
                    "highest_has_been_placed"]:
            return False
        if bar >= self._attempt_params[
                "lowest_must_appear_by"] and not self._attempt_params[
                    "lowest_has_been_placed"]:
            return False
        return True

    ##########################################
    ########### insert functions #############

    def _bury_indices(self, note: Note, index: tuple) -> None:
        (bar, beat) = index
        self._stored_indices.append([])
        for i in range(1, note.get_duration()):
            new_beat, new_bar = beat + (i / 2), bar
            while new_beat >= 4:
                new_beat -= 4
                new_bar += 1
            if (new_bar, new_beat) in self._counterpoint_obj:
                self._stored_indices[-1].append((new_bar, new_beat))
                del self._counterpoint_obj[(new_bar, new_beat)]
                self._all_indices.remove((new_bar, new_beat))
                self._remaining_indices.remove((new_bar, new_beat))

    def _unbury_indices(self, note: Note, index: tuple) -> None:
        i = len(self._counterpoint_lst) + 1
        while len(self._stored_indices[-1]) > 0:
            next_index = self._stored_indices[-1].pop()
            self._all_indices.insert(i, next_index)
            self._remaining_indices.append(next_index)
            self._counterpoint_obj[next_index] = None
        self._stored_indices.pop()

    def _check_for_highest_and_lowest(self, note: Note, index: tuple) -> None:
        if self._mr.is_unison(note, self._attempt_params["highest"]):
            self._attempt_params["highest_has_been_placed"] = True
        if self._mr.is_unison(note, self._attempt_params["lowest"]):
            self._attempt_params["lowest_has_been_placed"] = True

    def _check_for_on_beat_whole_note(self, note: Note, index: tuple) -> None:
        (bar, beat) = index
        if beat == 0 and note.get_duration() >= 8:
            self._attempt_params["num_on_beat_whole_notes_placed"] += 1

    def _check_if_new_run_is_added(self, note: Note, index: tuple) -> None:
        run_length = 0
        for i in range(len(self._counterpoint_lst) - 1, -1, -1):
            dur = self._counterpoint_lst[i].get_duration()
            if dur > 2:
                break
            run_length += dur / 2
        # if run_length > 7:
        #     print("run length:", run_length)
        if run_length == 4:
            self._attempt_params["num_runs_placed"] += 1
        if run_length == self._attempt_params["min_length_of_max_quarter_run"]:
            self._attempt_params["max_quarter_run_has_been_placed"] = True

    def _check_if_eighths_are_added(self, note: Note, index: tuple) -> None:
        (bar, beat) = index
        if beat == 1.5: self._attempt_params["eighths_have_been_placed"] = True

    ##########################################
    ########### final checks #################

    def _parameters_are_correct(self) -> bool:
        # print("num runs placed:", self._attempt_params["num_runs_placed"])
        # print("max run has been placed?", self._attempt_params["max_quarter_run_has_been_placed"])
        return self._attempt_params["num_runs_placed"] >= self._attempt_params[
            "min_runs_of_length_4_or_more"] and self._attempt_params[
                "max_quarter_run_has_been_placed"]

    def _has_only_one_octave(self) -> bool:
        num_octaves = 0
        for i in range(
                0 if
                self._counterpoint_lst[0].get_accidental() != ScaleOption.REST
                else 1,
                len(self._counterpoint_lst) - 1):
            if abs(self._counterpoint_lst[i].get_scale_degree_interval(
                    self._counterpoint_lst[i + 1])) == 8:
                num_octaves += 1
                if num_octaves > 1:
                    return False
        return True

    def _no_unresolved_leading_tones(self) -> bool:
        for i in range(1, self._length - 2):
            if (i, 0) not in self._counterpoint_obj:
                notes_to_check = []
                for index in [(i - 1, 0), (i - 1, 1), (i - 1, 2), (i, 2)]:
                    if index in self._counterpoint_obj:
                        notes_to_check.append(self._counterpoint_obj[index])
                for j, note in enumerate(notes_to_check):
                    if self._mr.is_sharp(note):
                        resolved = False
                        for k in range(j + 1, len(notes_to_check)):
                            if note.get_chromatic_interval(
                                    notes_to_check[k]) == 1:
                                resolved = True
                        if not resolved: return False
        return True

    ##########################################
    ########### scoring ######################

    def _score_solution(self, solution: list[Note]) -> int:
        score = 0
        self._map_solution_onto_counterpoint_dict(solution)
        num_ties = 0
        num_tied_dotted_halfs = 0
        num_tied_wholes = 0
        ties = [False] * (self._length - 2)
        for i in range(1, self._length - 1):
            if (i, 0) not in self._counterpoint_obj:
                ties[i - 1] = True
                num_ties += 1
                if (i - 1, 2) in self._counterpoint_obj:
                    if self._counterpoint_obj[(i - 1, 2)].get_duration() == 6:
                        num_tied_dotted_halfs += 1
                    else:
                        num_tied_wholes += 1
        ideal_ties = 3 if self._length < 12 else 4
        score += abs(ideal_ties - num_ties) * 10
        score += abs(num_tied_wholes - num_tied_dotted_halfs) * 5
        has_isolated_tie = False
        for i in range(1, len(ties) - 1):
            if ties[i - 1] == False and ties[i] == True and ties[i +
                                                                 1] == False:
                has_isolated_tie = True
        if has_isolated_tie: score -= 12
        num_quarter_runs_starting_on_beat = 0
        num_quarter_runs_starting_on_beat_of_length_two = 0
        num_other_two_note_quarter_runs = 0
        for i, index in enumerate(self._all_indices):
            (bar, beat) = index
            if beat == 0 and self._counterpoint_lst[i].get_duration(
            ) == 2 and self._counterpoint_lst[i - 1].get_duration() != 2:
                num_quarter_runs_starting_on_beat += 1
                if self._counterpoint_lst[i + 2].get_duration() != 2:
                    num_quarter_runs_starting_on_beat_of_length_two += 1
            if beat == 2 and self._counterpoint_lst[i].get_duration(
            ) == 2 and self._counterpoint_lst[i - 1].get_duration() != 2:
                if self._counterpoint_lst[i + 2].get_duration() != 2:
                    num_other_two_note_quarter_runs += 1
        score += num_quarter_runs_starting_on_beat * 60 + num_quarter_runs_starting_on_beat_of_length_two * 60 + num_other_two_note_quarter_runs * 45
        num_fifths, num_octaves = 0, 0
        for i in range(1, self._length - 2):
            if (i, 0) in self._counterpoint_obj:
                intvl = self._cantus[i].get_chromatic_interval(
                    self._counterpoint_obj[(i, 0)])
                if intvl in [-19, -7, 7, 19]: num_fifths += 1
                elif intvl in [-12, 0, 12]: num_octaves += 1
        score += num_fifths * 30 + num_octaves * 10
        num_steps = 0
        for i in range(len(self._counterpoint_lst) - 1):
            if abs(self._counterpoint_lst[i].get_scale_degree_interval(
                    self._counterpoint_lst[i + 1])) == 2:
                num_steps += 1
        score += math.floor(
            150 * abs(.712 - (num_steps / (len(self._counterpoint_lst) - 1))))
        return score

    def _map_solution_onto_counterpoint_dict(self,
                                             solution: list[Note]) -> None:
        self._counterpoint_obj = {}
        self._counterpoint_lst = []
        self._all_indices = []
        bar, beat = 0, 0
        self._all_indices = []
        for note in solution:
            self._counterpoint_obj[(bar, beat)] = note
            self._counterpoint_lst.append(note)
            self._all_indices.append((bar, beat))
            beat += note.get_duration() / 2
            while beat >= 4:
                beat -= 4
                bar += 1

    def _is_consonant(self, note1: Note, note2: Note) -> bool:
        (sdg_interval, chro_interval) = self._mr.get_intervals(note1, note2)
        if sdg_interval not in LegalIntervalsFifthSpecies["harmonic_scalar"]:
            return False
        if chro_interval not in LegalIntervalsFifthSpecies[
                "harmonic_chromatic"]:
            return False
        if (sdg_interval, chro_interval
            ) in LegalIntervalsFifthSpecies["forbidden_combinations"]:
            return False
        return True
class GenerateTwoPartFourthSpecies:

    def __init__(self, length: int = None, mode: ModeOption = None, octave: int = 4, orientation: Orientation = Orientation.ABOVE):
        self._orientation = orientation
        self._mode = mode or ModeOption.DORIAN
        self._length = length or 8 + math.floor(random() * 5) #todo: replace with normal distribution
        self._octave = octave
        self._mr = ModeResolver(self._mode)
        gcf = GenerateCantusFirmus(self._length, self._mode, self._octave)
        cf = None 
        #if the Cantus Firmus doesn't generate, we have to try again
        #also, for anything above the first species, the Cantus Firmus must end stepwise
        while cf is None or abs(cf.get_note(self._length - 2).get_scale_degree_interval(cf.get_note(self._length - 1))) > 2:
            cf = gcf.generate_cf()
        self._cantus_object = cf
        self._cantus = cf.get_notes()

    def print_counterpoint(self):
        print("  CANTUS FIRMUS:       COUNTERPOINT:")
        for i in range(self._length):
            for j in [0, 2]:
                cntpt_note = self._counterpoint[(i, j)] if (i, j) in self._counterpoint else ""
                if j == 0:
                    print("  " + str(self._cantus[i]) + "  " + str(cntpt_note))
                else:
                    print("                       " + str(cntpt_note))

    def get_optimal(self):
        if len(self._solutions) == 0:
            return None 
        optimal = self._solutions[0]
        print("optimal solution")
        for n in optimal: print(n)
        self._map_solution_onto_counterpoint_dict(optimal)
        self.print_counterpoint()
        return [optimal, self._cantus]
            
    def generate_2p4s(self):
        start_time = time()
        print("MODE = ", self._mode.value["name"])
        self._solutions = []
        def attempt():
            self._num_backtracks = 0
            self._solutions_this_attempt = 0
            initialized = self._initialize()
            while not initialized:
                initialized = self._initialize()
            self._backtrack()
        attempts = 0
        attempt()
        while len(self._solutions) < 1 and attempts < 20:
            print("attempt", attempts)
            attempt()
            attempts += 1
        print("number of attempts:", attempts)
        print("number of solutions:", len(self._solutions))
        if len(self._solutions) > 0:
            self._solutions.sort(key = lambda sol: self._score_solution(sol)) 

    def _initialize(self) -> bool:
        indices = []
        for i in range(self._length - 1):
            indices += [(i, 0), (i, 2)]
        indices += [(self._length - 1, 0)]
        self._all_indices = indices[:]
        self._remaining_indices = indices[:]
        self._remaining_indices.reverse()
        #initialize counterpoint data structure, that will map indices to notes
        counterpoint = {}
        for index in self._all_indices: counterpoint[index] = None 
        self._counterpoint = counterpoint
        lowest, highest = None, None
        vocal_range = randint(5, 8)
        if self._orientation == Orientation.ABOVE:
            lowest = self._mr.get_default_note_from_interval(self._cantus_object.get_highest_note(), [-3, -2, 1, 2, 3, 4][randint(0, 5)])
            highest = self._mr.get_default_note_from_interval(lowest, vocal_range)
        else:
            highest = self._mr.get_default_note_from_interval(self._cantus_object.get_lowest_note(), [-4, -3, -2, 1, 2, 3][randint(0, 5)])
            lowest = self._mr.get_default_note_from_interval(highest, vocal_range * -1)

        valid_pitches = [lowest, highest] #order is unimportant
        for i in range(2, vocal_range):
            valid_pitches += self._mr.get_notes_from_interval(lowest, i)



        self._highest, self._lowest = highest, lowest
        self._highest_must_appear_by = randint(2, self._length - 2)
        self._lowest_must_appear_by = randint(2 if self._highest_must_appear_by >= 4 else 4, self._length - 1)
        self._valid_pitches = valid_pitches
        self._highest_has_been_placed = False 
        self._lowest_has_been_placed = False 
        return True 

    def _backtrack(self) -> None:
        if (self._num_backtracks > 2000 and self._solutions_this_attempt == 0) or self._num_backtracks > 20000:
            return 
        if self._solutions_this_attempt >= 100:
            return 
        self._num_backtracks += 1
        if len(self._remaining_indices) == 0:
            # print("found possible solution!")
            sol = []
            for i in range(len(self._all_indices)):
                note_to_add = self._counterpoint[self._all_indices[i]]
                note_to_add_copy = Note(note_to_add.get_scale_degree(), note_to_add.get_octave(), note_to_add.get_duration(), note_to_add.get_accidental())
                sol.append(note_to_add_copy)
            if self._passes_final_checks(sol):
                # print("FOUND SOLUTION!")
                self._solutions.append(sol)
                self._solutions_this_attempt += 1
            return 
        (bar, beat) = self._remaining_indices.pop() 
        candidates = None
        if bar == 0 and (beat == 0 or self._counterpoint[(0, 0)].get_accidental() == ScaleOption.REST):
            candidates = list(filter(lambda n: self._cantus[0].get_chromatic_interval(n) in [-12, 0, 7, 12], self._valid_pitches))
        else:
            candidates = list(filter(lambda n: self._passes_insertion_checks(n, (bar, beat)), self._valid_pitches)) 
        if bar == 0 and beat == 0:
            candidates.append(Note(1, 0, 4, accidental = ScaleOption.REST))
            shuffle(candidates)
        if bar == self._length - 1:
            candidates = list(filter(lambda n: self._valid_last_note(n), candidates))
        for candidate in candidates:
            #start by making a copy of the note
            candidate = Note(candidate.get_scale_degree(), candidate.get_octave(), 8, candidate.get_accidental())
            temp_highest_placed, temp_lowest_placed = self._highest_has_been_placed, self._lowest_has_been_placed
            if self._mr.is_unison(candidate, self._highest): self._highest_has_been_placed = True  
            if self._mr.is_unison(candidate, self._lowest): self._lowest_has_been_placed = True 
            (may_be_tied, must_be_tied) = self._get_tied_options(candidate, (bar, beat))
            if not must_be_tied:
                candidate.set_duration(4 if bar != self._length - 1 else 16)
                self._counterpoint[(bar, beat)] = candidate 
                if self._current_chain_is_legal((bar, beat)):
                    self._backtrack()
            if may_be_tied or (bar == self._length - 2 and beat == 0):
                candidate.set_duration(8)
                index_to_remove = (bar, 2) if beat == 0 else (bar + 1, 0)
                index_position_all, index_position_remaining = self._all_indices.index(index_to_remove), self._remaining_indices.index(index_to_remove)
                self._all_indices.remove(index_to_remove)
                self._remaining_indices.remove(index_to_remove)
                del self._counterpoint[index_to_remove]
                self._counterpoint[(bar, beat)] = candidate 
                if self._current_chain_is_legal((bar, beat)):
                    self._backtrack()
                self._all_indices.insert(index_position_all, index_to_remove)
                self._remaining_indices.insert(index_position_remaining, index_to_remove)
                self._counterpoint[index_to_remove] = None 
            self._highest_has_been_placed, self._lowest_has_been_placed = temp_highest_placed, temp_lowest_placed
        self._counterpoint[(bar, beat)] = None 
        self._remaining_indices.append((bar, beat))

    def _passes_insertion_checks(self, note: Note, index: tuple) -> bool:
        if not self._is_valid_melodic_insertion(note, index): return False #checks for properly resolved ascending sixths and non-adjacent cross relations 
        if not self._valid_harmonic_insertion(note, index): return False #makes sure all dissonances are resolved
        if not self._doesnt_create_parallels(note, index): return False #eliminates parallels and hidden fifths
        if not self._no_large_parallel_leaps(note, index): return False 
        if not self._no_cross_relations_with_cantus_firmus(note, index): return False 
        if not self._handles_highest_and_lowest(note, index): return False 
        return True 

    def _is_valid_melodic_insertion(self, note: Note, index: tuple) -> bool:
        (bar, beat) = index
        prev_note = self._get_prev_note(index)
        if not self._is_valid_adjacent(prev_note, note): return False 
        #check to make sure an ascending minor sixth is handled 
        note_before_prev = self._get_prev_note(self._get_prev_index(index))
        if note_before_prev is not None and note_before_prev.get_accidental() == ScaleOption.REST: note_before_prev = None
        if note_before_prev is not None and note_before_prev.get_chromatic_interval(prev_note) == 8 and prev_note.get_chromatic_interval(note) != -1:
            return False
        if note_before_prev is not None and note_before_prev.get_scale_degree_interval(note) == 1 and note_before_prev.get_chromatic_interval(note) != 0:
            return False
        if bar == self._length - 1 and abs(prev_note.get_scale_degree_interval(note)) != 2: return False
        if bar == self._length - 1 and prev_note.get_scale_degree_interval(note) == 2 and not self._mr.is_unison(prev_note, self._mr.get_leading_tone_of_note(note)): return False
        return True 

    def _valid_harmonic_insertion(self, note: Note, index: tuple) -> bool:
        (bar, beat) = index
        #case 1: beat == 0 -> test for dissonance in previous measure 
        #case 2: if previous note is tied: if dissonant, resolve it.  If not, see if it is consonant or a passing tone 
        if beat == 0:
            if not self._is_valid_harmonically(note, self._cantus[bar]): return False 
            if bar != 0 and not self._is_valid_harmonically(self._get_prev_note(index), self._cantus[bar - 1]):
                prev_note = self._get_prev_note(index)
                if self._counterpoint[(bar - 1, 0)].get_scale_degree_interval(prev_note) != prev_note.get_scale_degree_interval(note):
                    return False 
            return True 
        elif (bar, 0) in self._counterpoint:
            if self._is_valid_harmonically(note, self._cantus[bar]): return True 
            if abs(self._get_prev_note(index).get_scale_degree_interval(note)) != 2: return False 
            return True 
        else:
            if not self._is_valid_harmonically(self._get_prev_note(index), self._cantus[bar]) and self._get_prev_note(index).get_scale_degree_interval(note) != -2:
                return False 
            if not self._is_valid_harmonically(self._cantus[bar], note): return False 
            return True 

    def _doesnt_create_parallels(self, note: Note, index: tuple) -> bool:
        (bar, beat) = index 
        if beat != 0 or bar == 0: return True 
        if self._cantus[bar].get_chromatic_interval(note) not in [-19, -12, -7, 0, 7, 12, 19]: return True 
        if (bar - 1, 0) in self._counterpoint and self._cantus[bar].get_chromatic_interval(note) == self._cantus[bar].get_chromatic_interval(self._counterpoint[(bar - 1, 0)]):
            return False
        lower_interval, higher_interval = self._cantus[bar - 1].get_scale_degree_interval(self._cantus[bar]), self._get_prev_note(index).get_scale_degree_interval(note)
        if (lower_interval > 0 and higher_interval > 0) or (lower_interval < 0 and higher_interval < 0):
            return False 
        return True 

    def _no_large_parallel_leaps(self, note: Note, index: tuple) -> bool:
        (bar, beat) = index 
        if beat == 2 or (bar - 1, 2) not in self._counterpoint: return True 
        lower_interval, higher_interval = self._cantus[bar - 1].get_scale_degree_interval(self._cantus[bar]), self._get_prev_note(index).get_scale_degree_interval(note)
        if abs(lower_interval > 2) and abs(higher_interval) > 2 and (abs(lower_interval) > 4 or abs(higher_interval) > 4) and ((lower_interval > 0 and higher_interval > 0) or (lower_interval < 0) and higher_interval < 0):
            return False 
        return True 

    def _no_cross_relations_with_cantus_firmus(self, note: Note, index: tuple) -> bool:
        (bar, beat) = index
        if bar > 0 and beat == 0 and self._cantus[bar - 1].get_scale_degree_interval(note) in [-8, 1, 8] and self._cantus[bar - 1].get_chromatic_interval(note) not in [-12, 0, 12]:
            return False 
        if beat == 2 and self._cantus[bar + 1].get_scale_degree_interval(note) in [-8, 1, 8] and self._cantus[bar + 1].get_chromatic_interval(note) not in [-12, 0, 12]:
            return False 
        return True 

    def _handles_highest_and_lowest(self, note: Note, index: tuple) -> bool:
        (bar, beat) = index 
        if self._highest_must_appear_by == bar and not self._highest_has_been_placed and not self._mr.is_unison(self._highest, note): return False 
        if self._highest_has_been_placed and self._mr.is_unison(note, self._highest): return False 
        if self._lowest_must_appear_by == bar and not self._lowest_has_been_placed and not self._mr.is_unison(self._lowest, note): return False 
        return True 

    def _valid_last_note(self, note: Note) -> bool:
        return self._cantus[self._length - 1].get_chromatic_interval(note) in [-12, 0, 12]

    def _get_tied_options(self, note: Note, index: tuple) -> tuple:
        (bar, beat) = index 
        if bar >= self._length - 2 or beat == 0 or not self._is_valid_harmonically(self._cantus[bar], note): return (False, False)
        (may_be_tied, must_be_tied) = (False, False)
        next_harmonic_interval = self._cantus[bar + 1].get_scale_degree_interval(note)
        if next_harmonic_interval in [-9, -2, 4, 7, 11] or (next_harmonic_interval == -5 and self._cantus[bar + 1].get_chromatic_interval(note) == -8):
            may_be_tied, must_be_tied = True, True
        elif self._is_valid_harmonically(self._cantus[bar + 1], note):
            may_be_tied = True 
        return (may_be_tied, must_be_tied)

    def _current_chain_is_legal(self, index: tuple) -> bool:
        current_chain = []
        for i in range(self._all_indices.index(index) + 1):
            next_note = self._counterpoint[self._all_indices[i]]
            current_chain.append(next_note)
        result = self._span_is_valid(current_chain)
        return result

    def _span_is_valid(self, span: list[Note]) -> bool:
        if len(span) < 3: return True 
        last_second_species_chain = [span[-1]]
        search_index = len(span) - 2
        while search_index >= 0 and span[search_index].get_duration() == 4:
            last_second_species_chain.append(span[search_index])
            search_index -= 1
        if len(last_second_species_chain) < 3: return True 
        last_second_species_chain.reverse()
        intervals = []
        for i in range(len(last_second_species_chain) - 1):
            intervals.append(last_second_species_chain[i].get_scale_degree_interval(last_second_species_chain[i + 1]))
        for i, interval in enumerate(intervals):
            if interval >= 4:
                for j in range(i - 1, -1, -1):
                    if intervals[j] < 0: break 
                    if intervals[j] > 2: return False 
            if interval <= -4:
                for j in range(i + 1, len(intervals)):
                    if intervals[j] > 0: break
                    if intervals[j] < -2: return False 
        #check for repeated notes in end of chain:
        if len(span) > 3 and self._mr.is_unison(span[-4], span[-2]) and self._mr.is_unison(span[-3], span[-1]): 
            return False 
        if len(span) > 4 and self._mr.is_unison(span[-1], span[-3]) and self._mr.is_unison(span[-1], span[-5]):
            return False 
        if len(span) > 5:
            repetitions = 0
            for i in range(-5, 0): 
                if self._mr.is_unison(span[-6], span[i]): repetitions += 1
                if repetitions == 2: 
                    return False
        return True 

    def _passes_final_checks(self, solution: list[Note]) -> bool:
        if len(solution) >= self._length * 1.4: return False
        return self._leaps_filled_in(solution)

    def _leaps_filled_in(self, solution: list[Note]) -> bool:
        # print("running leaps filled in with solution:")
        # for n in solution: print(n)
        # for i in range(1, len(solution) - 1):
        #     interval = solution[i - 1].get_scale_degree_interval(solution[i])
        #     #for leaps down, we either need the note below the top note or any higher note 
        #     if interval < -2:
        #         handled = False 
        #         for j in range(i + 1, len(solution)):
        #             if solution[i - 1].get_scale_degree_interval(solution[j]) >= -2:
        #                 handled = True
        #                 break
        #         if not handled: 
        #             print("intervals not properly handled")
        #             return False 
        return True

    def _map_solution_onto_counterpoint_dict(self, solution: list[Note]) -> None:
        self._counterpoint = {}
        bar, beat = 0, 0
        self._all_indices = []
        for note in solution:
            self._counterpoint[(bar, beat)] = note
            self._all_indices.append((bar, beat))
            beat += note.get_duration() / 2 
            while beat >= 4:
                beat -= 4
                bar += 1

    def _score_solution(self, solution: list[Note]) -> int:
        score = 0
        self._map_solution_onto_counterpoint_dict(solution)
        #add 5 points for every measure that isn't a suspension and 12 points for every measure that isn't tied
        for i in range(1, self._length - 1):
            if (i, 0) in self._counterpoint: score += 12
            elif self._is_valid_harmonically(self._counterpoint[(i - 1, 2)], self._cantus[i]): score += 5
        #add an additional 15 points if penultimate measure is not tied
        if (self._length - 2, 0) in self._counterpoint: score += 15
        return score 

    def _is_valid_adjacent(self, note1: Note, note2: Note) -> bool:
        sdg_interval = note1.get_scale_degree_interval(note2)
        chro_interval = note1.get_chromatic_interval(note2)
        if (self._mr.is_leading_tone(note1) or self._mr.is_leading_tone(note2)) and abs(sdg_interval) > 3: return False 
        if ( sdg_interval in LegalIntervalsFourthSpecies["adjacent_melodic_scalar"] 
            and chro_interval in LegalIntervalsFourthSpecies["adjacent_melodic_chromatic"]
            and (sdg_interval, chro_interval) not in LegalIntervalsFourthSpecies["forbidden_combinations"] ):
            return True 
        return False 

    def _is_valid_outline(self, note1: Note, note2: Note) -> bool:
        sdg_interval = note1.get_scale_degree_interval(note2)
        chro_interval = note1.get_chromatic_interval(note2)
        if ( sdg_interval in LegalIntervalsFourthSpecies["outline_melodic_scalar"] 
            and chro_interval in LegalIntervalsFourthSpecies["outline_melodic_chromatic"]
            and (sdg_interval, chro_interval) not in LegalIntervalsFourthSpecies["forbidden_combinations"] ):
            return True 
        return False 

    def _is_valid_harmonically(self, note1: Note, note2: Note) -> bool:
        sdg_interval = note1.get_scale_degree_interval(note2)
        chro_interval = note1.get_chromatic_interval(note2)
        if ( sdg_interval in LegalIntervalsFourthSpecies["harmonic_scalar"] 
            and chro_interval in LegalIntervalsFourthSpecies["harmonic_chromatic"]
            and (sdg_interval, chro_interval) not in LegalIntervalsFourthSpecies["forbidden_combinations"] ):
            return True 
        return False 

    def _get_prev_note(self, index: tuple) -> Note:
        prev_index = self._get_prev_index(index)
        return None if prev_index is None else self._counterpoint[prev_index]

    def _get_next_note(self, index: tuple) -> Note:
        next_index = self._get_next_index(index)
        return None if next_index is None else self._counterpoint[next_index]

    def _get_prev_index(self, index: tuple) -> tuple:
        if index is None: return None
        i = self._all_indices.index(index)
        if i == 0: return None
        return self._all_indices[i - 1]

    def _get_next_index(self, index: tuple) -> tuple:
        i = self._all_indices.index(index)
        if i == len(self._all_indices) - 1: return None 
        return self._all_indices[i + 1]
Пример #3
0
class GenerateImitationTheme:
    def __init__(self, mode: ModeOption, hexachord: HexachordOption,
                 highest: Note, lowest: Note):
        self._mode = mode
        self._length = randint(3, 6)
        self._hexachord = hexachord
        self._mr = ModeResolver(self._mode)
        self._attempt_params = {
            "first_note": None,
            "second_note": None,
            "second_note_must_appear_by": None,
            "second_note_has_been_placed": None,
            "highest_has_been_placed": None,
            "highest": highest,
            "lowest": lowest
        }
        self._insertion_checks = [
            self._handles_adjacents, self._handles_interval_order,
            self._handles_nearby_augs_and_dims,
            self._handles_nearby_leading_tones,
            self._handles_ascending_minor_sixth,
            self._handles_ascending_quarter_leaps,
            self._handles_descending_quarter_leaps, self._handles_repetition,
            self._handles_highest, self._handles_resolution_of_anticipation,
            self._handles_repeated_two_notes,
            self._handles_quarter_between_two_leaps,
            self._handles_upper_neighbor, self._stops_quarter_leaps,
            self._stops_leaps_outside_of_hexachord
        ]
        self._rhythm_filters = [
            self._handles_consecutive_quarters, self._handles_repeated_note,
            self._handles_rhythm_after_descending_quarter_leap,
            self._handles_repeated_dotted_halfs, self._handles_slow_beginning,
            self._handles_consecutive_whole_notes,
            self._handles_consecutive_syncopation,
            self._prevents_two_note_quarter_runs,
            self._no_quarter_runs_after_whole_notes
        ]
        self._index_checks = [self._both_notes_placed]
        self._change_params = [self._check_for_highest_and_second_note]
        self._final_checks = [
            self._has_only_one_octave,
            # self._starts_with_longer
        ]
        self._params = ["second_note_has_been_placed"]

    def print_counterpoint(self):
        print("  FIFTH SPECIES:")
        for i in range(self._length):
            for j in range(4):
                cntpt_note = str(self._counterpoint_obj[(i, j)]) if (
                    i, j) in self._counterpoint_obj else ""
                if cntpt_note is None: cntpt_note = "None"
                show_index = "    "
                if j == 0:
                    show_index = str(i) + ":  " if i < 10 else str(i) + ": "
                print(show_index + "   " + str(cntpt_note))

    def get_optimal(self):
        if len(self._solutions) == 0:
            return None
        optimal = self._solutions[0]
        self._map_solution_onto_counterpoint_dict(optimal)
        # self.print_counterpoint()
        return [optimal]

    def generate_theme(self):
        self._solutions = []
        attempts = 1
        while len(self._solutions) < 1 and attempts < 100:
            # if attempts % 1000 == 0:
            # print("attempt", attempts)
            self._num_backtracks = 0
            self._solutions_this_attempt = 0
            initialized = self._initialize()
            self._backtrack()
            attempts += 1
        # print("number of attempts:", attempts)
        # print("number of solutions:", len(self._solutions))
        if len(self._solutions) > 0:
            shuffle(self._solutions)
            self._solutions.sort(key=lambda sol: self._score_solution(sol))

    def _initialize(self) -> bool:
        indices = []
        for i in range(self._length):
            indices += [(i, 0), (i, 1), (i, 2), (i, 3)]
        self._all_indices = indices[:]
        self._remaining_indices = indices[:]
        self._remaining_indices.reverse()
        #initialize counterpoint data structure, that will map indices to notes
        self._counterpoint_obj = {}
        for index in self._all_indices:
            self._counterpoint_obj[index] = None
        #also initialize counterpoint data structure as list
        self._counterpoint_lst = []
        #initialize parameters for this attempt
        hex_notes = self._mr.get_scale_degrees_of_outline(self._hexachord)
        self._attempt_params["first_note"], self._attempt_params[
            "second_note"] = hex_notes[0], hex_notes[1]
        if random() < 0.5:
            self._attempt_params["first_note"], self._attempt_params[
                "second_note"] = hex_notes[1], hex_notes[0]
        self._attempt_params["second_note_must_appear_by"] = randint(
            1, self._length - 2)
        self._store_params = []
        self._stored_indices = []
        self._valid_pitches = [
            self._attempt_params["lowest"], self._attempt_params["highest"]
        ]  #order is unimportant
        for i in range(
                2, self._attempt_params["lowest"].get_scale_degree_interval(
                    self._attempt_params["highest"])):
            self._valid_pitches.append(
                self._mr.get_default_note_from_interval(
                    self._attempt_params["lowest"], i))
        return True

    def _backtrack(self) -> None:
        if (self._solutions_this_attempt > 0 or self._num_backtracks > 50000
            ) or (self._solutions_this_attempt == 0
                  and self._num_backtracks > 1000000):
            return
        self._num_backtracks += 1
        # if self._num_backtracks % 10000 == 0:
        # print("backtrack number:", self._num_backtracks)
        if len(self._remaining_indices) == 0:
            #print("found possible solution")
            if self._passes_final_checks():
                # if self._solutions_this_attempt == 0:
                # print("FOUND SOLUTION!")
                self._solutions.append(self._counterpoint_lst[:])
                self._solutions_this_attempt += 1
            return
        (bar, beat) = self._remaining_indices.pop()

        if self._passes_index_checks((bar, beat)):
            candidates = list(
                filter(lambda n: self._passes_insertion_checks(n, (bar, beat)),
                       self._valid_pitches))
            shuffle(candidates)
            # print("candidates for index", bar, beat, ": ", len(candidates))
            notes_to_insert = []
            for candidate in candidates:
                durations = self._get_valid_durations(candidate, (bar, beat))
                for dur in durations:
                    if dur in [2, 6, 4, 8, 12, 16]:
                        notes_to_insert.append(
                            Note(candidate.get_scale_degree(),
                                 candidate.get_octave(),
                                 dur,
                                 accidental=candidate.get_accidental()))
            shuffle(notes_to_insert)
            for note_to_insert in notes_to_insert:
                self._insert_note(note_to_insert, (bar, beat))
                self._backtrack()
                self._remove_note(note_to_insert, (bar, beat))
        self._remaining_indices.append((bar, beat))

    def _passes_index_checks(self, index: tuple) -> bool:
        for check in self._index_checks:
            if not check(index): return False
        return True

    def _passes_insertion_checks(self, note: Note, index: tuple) -> bool:
        (bar, beat) = index
        if bar == 0 and beat == 0:
            return self._check_starting_pitch(note)
        for check in self._insertion_checks:
            if not check(note, (bar, beat)):
                # print("failed insertion check", check.__name__, str(note), index)
                return False
        # print("passed insertion checks!", str(note), index)
        return True

    def _get_valid_durations(self, note: Note, index: tuple) -> set:
        (bar, beat) = index
        if bar == 0 and beat == 0:
            if self._length == 3:
                return {6}
            else:
                return {16, 12, 8, 6}
        durs = self._get_durations_from_beat(beat)
        prev_length = len(durs)
        for check in self._rhythm_filters:
            durs = check(note, index, durs)
            if len(durs) == 0: break
        return durs

    def _insert_note(self, note: Note, index: tuple) -> set:
        self._counterpoint_lst.append(note)
        self._counterpoint_obj[index] = note
        self._store_params.append({})
        for param in self._params:
            self._store_params[-1][param] = self._attempt_params[param]
        self._bury_indices(note, index)
        for check in self._change_params:
            check(note, index)

    def _remove_note(self, note: Note, index: tuple) -> set:
        self._counterpoint_lst.pop()
        self._counterpoint_obj[index] = None
        for param in self._params:
            self._attempt_params[param] = self._store_params[-1][param]
        self._store_params.pop()
        self._unbury_indices(note, index)

    def _passes_final_checks(self) -> bool:
        for check in self._final_checks:
            if not check():
                # print("failed final check:", check.__name__)
                return False
        return True

    ######################################
    ########## insertion checks ##########

    def _check_starting_pitch(self, note: Note) -> bool:
        if note.get_accidental() != ScaleOption.NATURAL: return False
        if note.get_scale_degree() != self._attempt_params["first_note"]:
            return False
        return True

    def _handles_adjacents(self, note: Note, index: tuple) -> bool:
        (bar, beat) = index
        (sdg_interval,
         chro_interval) = self._mr.get_intervals(self._counterpoint_lst[-1],
                                                 note)
        if sdg_interval not in LegalIntervalsFifthSpecies[
                "adjacent_melodic_scalar"]:
            return False
        if chro_interval not in LegalIntervalsFifthSpecies[
                "adjacent_melodic_chromatic"]:
            return False
        if (sdg_interval, chro_interval
            ) in LegalIntervalsFifthSpecies["forbidden_combinations"]:
            return False
        return True

    def _handles_interval_order(self, note: Note, index: tuple) -> bool:
        potential_interval = self._counterpoint_lst[
            -1].get_scale_degree_interval(note)
        if potential_interval >= 3:
            for i in range(len(self._counterpoint_lst) - 2, -1, -1):
                interval = self._counterpoint_lst[i].get_scale_degree_interval(
                    self._counterpoint_lst[i + 1])
                if interval < 0: return True
                if interval > 2: return False
        if potential_interval == 2:
            segment_has_leap = False
            for i in range(len(self._counterpoint_lst) - 2, -1, -1):
                interval = self._counterpoint_lst[i].get_scale_degree_interval(
                    self._counterpoint_lst[i + 1])
                if interval < 0: return True
                if segment_has_leap: return False
                segment_has_leap = interval > 2
        if potential_interval == -2:
            segment_has_leap = False
            for i in range(len(self._counterpoint_lst) - 2, -1, -1):
                interval = self._counterpoint_lst[i].get_scale_degree_interval(
                    self._counterpoint_lst[i + 1])
                if interval > 0: return True
                if segment_has_leap or interval == -8: return False
                segment_has_leap = interval < -2
        if potential_interval <= -3:
            for i in range(len(self._counterpoint_lst) - 2, -1, -1):
                interval = self._counterpoint_lst[i].get_scale_degree_interval(
                    self._counterpoint_lst[i + 1])
                if interval > 0: return True
                if interval < -2: return False
        return True

    def _handles_nearby_augs_and_dims(self, note: Note, index: tuple) -> bool:
        if len(self._counterpoint_lst) < 2: return True
        if self._mr.is_cross_relation(
                note, self._counterpoint_lst[-2]
        ) and self._counterpoint_lst[-1].get_duration() <= 2:
            return False
        if self._counterpoint_lst[-2].get_duration(
        ) != 2 and self._counterpoint_lst[-1].get_duration() != 2:
            return True
        (sdg_interval,
         chro_interval) = self._mr.get_intervals(self._counterpoint_lst[-2],
                                                 note)
        return (abs(sdg_interval) != 2
                or abs(chro_interval) != 3) and (abs(sdg_interval) != 3
                                                 or abs(chro_interval) != 2)

    def _handles_nearby_leading_tones(self, note: Note, index: tuple) -> bool:
        (bar, beat) = index
        if beat == 2 and (
                bar - 1,
                2) in self._counterpoint_obj and self._counterpoint_obj[
                    (bar - 1, 2)].get_duration() > 4:
            if self._mr.is_sharp(self._counterpoint_obj[(
                    bar - 1, 2)]) and self._counterpoint_obj[
                        (bar - 1, 2)].get_chromatic_interval(note) != 1:
                return False
        if beat == 0 and bar != 0:
            prev_measure_notes = []
            for i, num in enumerate([0, 1, 1.5, 2, 3]):
                if (bar - 1,
                        num) in self._counterpoint_obj and self._mr.is_sharp(
                            self._counterpoint_obj[(bar - 1, num)]):
                    resolved = False
                    for j in range(i + 1, 5):
                        next_index = (bar - 1, [0, 1, 1.5, 2, 3][j])
                        if next_index in self._counterpoint_obj and self._counterpoint_obj[
                            (bar - 1, num)].get_chromatic_interval(
                                self._counterpoint_obj[next_index]) == 1:
                            resolved = True
                    if not resolved and self._counterpoint_obj[
                        (bar - 1, num)].get_chromatic_interval(note) != 1:
                        return False
        return True

    def _handles_ascending_minor_sixth(self, note: Note, index: tuple) -> bool:
        if len(self._counterpoint_lst) < 2: return True
        if self._counterpoint_lst[-2].get_chromatic_interval(
                self._counterpoint_lst[-1]) == 8:
            return self._counterpoint_lst[-1].get_chromatic_interval(
                note) == -1
        return True

    def _handles_ascending_quarter_leaps(self, note: Note,
                                         index: tuple) -> bool:
        (bar, beat) = index
        if self._counterpoint_lst[-1].get_scale_degree_interval(note) > 2:
            if beat % 2 == 1: return False
            if len(self._counterpoint_lst
                   ) >= 2 and self._counterpoint_lst[-1].get_duration() == 2:
                if self._counterpoint_lst[-2].get_scale_degree_interval(
                        self._counterpoint_lst[-1]) > 0:
                    return False
        return True

    def _handles_descending_quarter_leaps(self, note: Note,
                                          index: tuple) -> bool:
        (bar, beat) = index
        if len(self._counterpoint_lst) < 2: return True
        if self._counterpoint_lst[-2].get_scale_degree_interval(
                self._counterpoint_lst[-1]
        ) < -2 and self._counterpoint_lst[-1].get_duration() == 2:
            if self._counterpoint_lst[-1].get_scale_degree_interval(note) == 2:
                return True
            return self._counterpoint_lst[-2].get_scale_degree_interval(
                note) in [-2, 1, 2]
        return True

    def _handles_repetition(self, note: Note, index: tuple) -> bool:
        (bar, beat) = index
        if self._mr.is_unison(self._counterpoint_lst[-1], note) and (
                beat != 2 or self._counterpoint_lst[-1].get_duration() != 2):
            return False
        return True

    def _handles_highest(self, note: Note, index: tuple) -> bool:
        if self._attempt_params[
                "highest_has_been_placed"] and self._mr.is_unison(
                    self._attempt_params["highest"], note):
            return False
        return True

    def _handles_resolution_of_anticipation(self, note: Note,
                                            index: tuple) -> bool:
        if len(self._counterpoint_lst) < 2 or not self._mr.is_unison(
                self._counterpoint_lst[-2], self._counterpoint_lst[-1]):
            return True
        return self._counterpoint_lst[-1].get_scale_degree_interval(note) == -2

    def _handles_repeated_two_notes(self, note: Note, index: tuple) -> bool:
        (bar, beat) = index
        if len(self._counterpoint_lst) < 3: return True
        if not self._mr.is_unison(
                self._counterpoint_lst[-3],
                self._counterpoint_lst[-1]) or not self._mr.is_unison(
                    self._counterpoint_lst[-2], note):
            return True
        if self._counterpoint_lst[-1].get_scale_degree_interval(note) != 2:
            return False
        if self._counterpoint_lst[-2].get_duration() != 8 or beat != 0:
            return False
        return True

    def _handles_quarter_between_two_leaps(self, note: Note,
                                           index: tuple) -> bool:
        if self._counterpoint_lst[-1].get_duration() != 2 or len(
                self._counterpoint_lst) < 2:
            return True
        first_interval, second_interval = self._counterpoint_lst[
            -2].get_scale_degree_interval(
                self._counterpoint_lst[-1]
            ), self._counterpoint_lst[-1].get_scale_degree_interval(note)
        if abs(first_interval) == 2 or abs(second_interval) == 2:
            return True
        if first_interval > 0 and second_interval < 0: return False
        if first_interval == -8 and second_interval == 8: return False
        return True

    def _handles_upper_neighbor(self, note: Note, index: tuple) -> bool:
        (bar, beat) = index
        if (beat % 2 == 0 and self._counterpoint_lst[-1].get_duration() == 2
                and self._counterpoint_lst[-1].get_scale_degree_interval(note)
                == -2 and len(self._counterpoint_lst) >= 2
                and self._counterpoint_lst[-2].get_scale_degree_interval(
                    self._counterpoint_lst[-1]) == 2
                and self._counterpoint_lst[-2].get_duration() != 2):
            return False
        return True

    def _stops_quarter_leaps(self, note: Note, index: tuple) -> bool:
        if index != (0, 0) and self._counterpoint_lst[-1].get_duration(
        ) == 2 and abs(self._counterpoint_lst[-1].get_scale_degree_interval(
                note)) != 2:
            return False
        return True

    def _stops_leaps_outside_of_hexachord(self, note: Note,
                                          index: tuple) -> bool:
        if index != (0, 0) and abs(self._counterpoint_lst[-1].
                                   get_scale_degree_interval(note)) > 2:
            hex_notes = [
                self._attempt_params["first_note"],
                self._attempt_params["second_note"]
            ]
            if self._counterpoint_lst[-1].get_scale_degree(
            ) not in hex_notes and note.get_scale_degree() not in hex_notes:
                return False
        return True

    ######################################
    ########## rhythms filters ###########

    def _get_durations_from_beat(self, beat: int) -> set:
        if beat == 3: return {2}
        if beat == 1: return {1, 2}
        if beat == 2: return {2, 4, 6, 8}
        if beat == 0: return {2, 4, 6, 8, 12}

    def _handles_consecutive_quarters(self, note: Note, index: tuple,
                                      durs: set) -> set:
        (bar, beat) = index
        if self._counterpoint_lst[-1].get_duration() != 2: return durs
        if self._counterpoint_lst[-1].get_scale_degree_interval(
                note) > 0 and beat == 2:
            durs.discard(4)
        if beat == 2 and self._counterpoint_lst[-2].get_duration(
        ) == 2 and self._counterpoint_lst[-1].get_duration(
        ) == 2 and self._counterpoint_lst[-3].get_duration() != 2:
            durs.discard(4)
        for i in range(len(self._counterpoint_lst) - 2, -1, -1):
            if self._counterpoint_lst[i].get_duration() != 2:
                return durs
            if abs(self._counterpoint_lst[i].get_scale_degree_interval(
                    self._counterpoint_lst[i + 1])) > 2:
                durs.discard(2)
                return durs
        return durs

    def _handles_repeated_note(self, note: Note, index: tuple,
                               durs: set) -> set:
        if self._mr.is_unison(self._counterpoint_lst[-1], note):
            durs.discard(4)
            durs.discard(2)
        return durs

    def _handles_rhythm_after_descending_quarter_leap(self, note: Note,
                                                      index: tuple,
                                                      durs: set) -> set:
        (bar, beat) = index
        if self._counterpoint_lst[-1].get_duration(
        ) == 2 and self._counterpoint_lst[-1].get_scale_degree_interval(
                note) < -2:
            durs.discard(8)
            durs.discard(6)
        return durs

    def _handles_repeated_dotted_halfs(self, note: Note, index: tuple,
                                       durs: set) -> set:
        (bar, beat) = index
        if (bar - 1,
                beat) in self._counterpoint_obj and self._counterpoint_obj[(
                    bar - 1, beat)].get_duration() == 6:
            durs.discard(6)
        return durs

    def _handles_slow_beginning(self, note: Note, index: tuple,
                                durs: set) -> set:
        (bar, beat) = index
        if bar <= self._length - 6:
            durs.discard(2)
            durs.discard(4)
            durs.discard(6)
        if bar <= self._length - 5:
            durs.discard(2)
            durs.discard(4)
        return durs

    def _handles_consecutive_whole_notes(self, note: Note, index: tuple,
                                         durs: set) -> set:
        (bar, beat) = index
        if len(self._counterpoint_lst
               ) >= 2 and self._counterpoint_lst[-2].get_duration(
               ) == 8 and self._counterpoint_lst[-1].get_duration() == 8:
            durs.discard(8)
        return durs

    def _handles_consecutive_half_notes(self, note: Note, index: tuple,
                                        durs: set) -> set:
        (bar, beat) = index
        if len(self._counterpoint_lst
               ) >= 2 and self._counterpoint_lst[-2].get_duration(
               ) == 4 and self._counterpoint_lst[-1].get_duration() == 4:
            durs.discard(4)
        return durs

    def _handles_consecutive_syncopation(self, note: Note, index: tuple,
                                         durs: set) -> set:
        (bar, beat) = index
        if beat == 2 and (bar, 0) not in self._counterpoint_obj:
            durs.discard(6)
            durs.discard(8)
        return durs

    def _prevents_two_note_quarter_runs(self, note: Note, index: tuple,
                                        durs: set) -> set:
        if len(self._counterpoint_lst) < 3: return durs
        if self._counterpoint_lst[-3].get_duration(
        ) != 2 and self._counterpoint_lst[-2].get_duration(
        ) == 2 and self._counterpoint_lst[-1].get_duration() == 2:
            return {2} if 2 in durs else set()
        return durs

    def _no_quarter_runs_after_whole_notes(self, note: Note, index: tuple,
                                           durs: set) -> set:
        (bar, beat) = index
        if bar != 0 and beat == 0 and self._counterpoint_lst[-1].get_duration(
        ) >= 8:
            durs.discard(2)
        return durs

    ##########################################
    ########### index checks #################

    def _both_notes_placed(self, index: tuple) -> bool:
        (bar, beat) = index
        if bar >= self._attempt_params[
                "second_note_must_appear_by"] and not self._attempt_params[
                    "second_note_has_been_placed"]:
            return False
        return True

    ##########################################
    ########### insert functions #############

    def _bury_indices(self, note: Note, index: tuple) -> None:
        (bar, beat) = index
        self._stored_indices.append([])
        for i in range(1, note.get_duration()):
            new_beat, new_bar = beat + (i / 2), bar
            while new_beat >= 4:
                new_beat -= 4
                new_bar += 1
            if (new_bar, new_beat) in self._counterpoint_obj:
                self._stored_indices[-1].append((new_bar, new_beat))
                del self._counterpoint_obj[(new_bar, new_beat)]
                self._all_indices.remove((new_bar, new_beat))
                self._remaining_indices.remove((new_bar, new_beat))

    def _unbury_indices(self, note: Note, index: tuple) -> None:
        i = len(self._counterpoint_lst) + 1
        while len(self._stored_indices[-1]) > 0:
            next_index = self._stored_indices[-1].pop()
            self._all_indices.insert(i, next_index)
            self._remaining_indices.append(next_index)
            self._counterpoint_obj[next_index] = None
        self._stored_indices.pop()

    def _check_for_highest_and_second_note(self, note: Note,
                                           index: tuple) -> None:
        if self._mr.is_unison(note, self._attempt_params["highest"]):
            self._attempt_params["highest_has_been_placed"] = True
        if note.get_accidental(
        ) == ScaleOption.NATURAL and note.get_scale_degree(
        ) == self._attempt_params["second_note"]:
            self._attempt_params["second_note_has_been_placed"] = True

    ##########################################
    ########### final checks #################

    def _has_only_one_octave(self) -> bool:
        num_octaves = 0
        for i in range(
                0 if
                self._counterpoint_lst[0].get_accidental() != ScaleOption.REST
                else 1,
                len(self._counterpoint_lst) - 1):
            if abs(self._counterpoint_lst[i].get_scale_degree_interval(
                    self._counterpoint_lst[i + 1])) == 8:
                num_octaves += 1
                if num_octaves > 1:
                    return False
        return True

    def _starts_with_longer(self) -> bool:
        if self._counterpoint_lst[0].get_duration() <= 8: return False
        return True

    ##########################################
    ########### scoring ######################

    def _score_solution(self, solution: list[Note]) -> int:
        score = 0
        self._map_solution_onto_counterpoint_dict(solution)
        if (self._length - 2, 0) in self._counterpoint_obj: score += 500
        num_ties = 0
        num_tied_dotted_halfs = 0
        num_tied_wholes = 0
        ties = [False] * (self._length - 2)
        for i in range(1, self._length - 1):
            if (i, 0) not in self._counterpoint_obj:
                ties[i - 1] = True
                num_ties += 1
                if (i - 1, 2) in self._counterpoint_obj:
                    if self._counterpoint_obj[(i - 1, 2)].get_duration() == 6:
                        num_tied_dotted_halfs += 1
                    else:
                        num_tied_wholes += 1
        ideal_ties = 1
        score += abs(ideal_ties - num_ties) * 10
        score += abs(num_tied_wholes - num_tied_dotted_halfs) * 7
        if self._counterpoint_lst[0].get_duration() == 6: score -= 1000
        return score

    def _map_solution_onto_counterpoint_dict(self,
                                             solution: list[Note]) -> None:
        self._counterpoint_obj = {}
        self._counterpoint_lst = []
        self._all_indices = []
        bar, beat = 0, 0
        self._all_indices = []
        for note in solution:
            self._counterpoint_obj[(bar, beat)] = note
            self._counterpoint_lst.append(note)
            self._all_indices.append((bar, beat))
            beat += note.get_duration() / 2
            while beat >= 4:
                beat -= 4
                bar += 1