Exemplo n.º 1
0
class EventSequence(object):
    """
    A class to collect a sequence of Event's ordered (increasing) by the Event's time value.
    The class contains the following event accounting structures:
    1) OrderedMap: ordering the events by time in a map that provides a floor() function.
    2) successor: a dict that maps events to successors.
    3) predecessor: a dict that maps events to predecessors.
    4) first: first event in the event sequence.
    5) last: last event in the event sequence.
    """

    def __init__(self, event_list=None):
        """
        Constructor.
        
        Args:
          event_list:  Any of None, a single Event, or a list of Events.
        """
        self.ordered_map = OrderedMap()
        
        self._successor = {}
        self._predecessor = {}
        self.__first = None
        self.__last = None
        
        if event_list:
            self.add(event_list)
    
    @property       
    def sequence_list(self):
        return list(self.ordered_map.get(x) for x in self.ordered_map.keys())
    
    @property
    def is_empty(self):
        return self.ordered_map.is_empty()
    
    def floor(self, time):
        return self.ordered_map.floor(time)
    
    def event(self, index):
        return self.ordered_map.get(index)
    
    def floor_event(self, time):
        floor_position = self.floor(time)
        return self.event(floor_position) if floor_position else None
    
    @property
    def first(self):
        return self.__first
    
    @property
    def last(self):
        return self.__last
    
    def add(self, new_members):
        """
        Add any of a single Event or a list of Events.
        
        Args:
          new_members: Any of a single Event or a list of events
        """
                
        if isinstance(new_members, list):
            mem_set = new_members
            inputt = [(e.time, e) for e in new_members]

        else:
            mem_set = [new_members]
            inputt = [(new_members.time, new_members)]
           
        for m in mem_set:
            if self.ordered_map.has_reverse(m):
                raise Exception('{0} already a member of sequence.'.format(m))  
            if not isinstance(m, Event):
                raise Exception('{0} is not an event.'.format(m)) 
            
        for i in inputt:
            if i[1].time not in self.ordered_map:
                self._add_successor_predecessor_maps(i[1])
            else:
                self._update_successor_predecessor_maps(i[1])
            self.ordered_map.insert(i[0], i[1])                  
        
    def remove(self, members): 
        """
        Remove any of a single Event or a list of Events already in the sequence.
        
        Args:
          members: Any of a single Event or a list of Events already in the sequence.
        """
        if isinstance(members, list):
            for member in members:
                self.remove(member)
        else:
            if not self.ordered_map.has_reverse(members):
                raise Exception('{0} not a member of sequence'.format(members))            
            self._remove_successor_predecessor_maps(members)
            self.ordered_map.remove_key(self.ordered_map.reverse_get(members))  
            
    def move_event(self, event, new_time):
        """
        Method to move event in sequence to a new time.
        
        Args:
          event: (Event) to move
          new_time: the new time setting for the event
        """
        if self.event(event.time) != event:
            raise Exception('Given event at time {0} not in sequence'.format(event.time))
        self.remove(event)
        event.time = new_time
        self.add(event)
            
    def _add_successor_predecessor_maps(self, event):
        fl_key = self.floor(event.time)
        if fl_key:
            a = self.event(fl_key)
            b = self._successor[a]  # could be None  event is between a and b
            self._successor[a] = event
            self._successor[event] = b
            self._predecessor[event] = a
            if b:
                self._predecessor[b] = event
            else:
                self.__last = event
        else:  # this event has to come first
            if self.__first:
                self._successor[event] = self.__first
                self._predecessor[self.__first] = event
                self._predecessor[event] = None
                self.__first = event
            else:
                self.__first = self.__last = event
                self._successor[event] = None
                self._predecessor[event] = None
            
    def _update_successor_predecessor_maps(self, event):
        e = self.event(event.time)
        self.remove(e)
        self._add_successor_predecessor_maps(event)
        pass
    
    def _remove_successor_predecessor_maps(self, event):
        a = self._predecessor[event]
        b = self._successor[event]
        del self._successor[event]
        del self._predecessor[event]
        if a:
            self._successor[a] = b
        else:
            self.__first = b
        if b:
            self._predecessor[b] = a
        else:
            self.__last = a
        
    def clear(self):
        self.ordered_map.clear()
        self._successor.clear()
        self._predecessor.clear()
        
    def successor(self, event):
        return self._successor[event] if event in self._successor else None
    
    def predecessor(self, event):
        return self._predecessor[event] if event in self._predecessor else None
        
    def __str__(self):
        return ', '.join(str(x) for x in self.sequence_list)
    
    def print_maps(self):
        print('---------')
        if self.__first:
            print('first={0}'.format(self.__first))
        else:
            print('first=None')
        if self.__first:
            print('last={0}'.format(self.__last))
        else:
            print('last=None')
        
        print('Successor:')
        for i in self._successor.items():
            print('   {0} --> {1}'.format(i[0].object if i[0] else 'None', i[1].object if i[1] else 'None'))

        print('Predecessor:')
        for i in self._predecessor.items():
            print('   {0} --> {1}'.format(i[0].object if i[0] else 'None', i[1].object if i[1] else 'None'))
Exemplo n.º 2
0
class TimeConversion(object):
    """
    Time conversion algorithms.
    1) Whole Time --> actual time
    2) actual time --> Wholec Time
    """

    def __init__(self, tempo_line, ts_line, max_position, pickup=Duration(0, 1)):
        """
        Constructor.
        
        Args:
          tempo_line: (EventSequence) of TempoEvent's
          ts_line: (EventSequence) of TimeSignatureEvent's
          max_position: Position of end of whole note time
          pickup: whole note time for a partial initial measure
          
        Assumption:
          tempo_line and ts_line cover position 0
          
        Exceptions:
          If pickup exceeds whole note time of the first time signature.
        """
        self.tempo_line = tempo_line
        self.ts_line = ts_line
        self.__max_position = max_position
        self.__pickup = pickup

        if not isinstance(max_position, Position):
            raise Exception('max_position argument must be Position not \'{0}\'.'.format(type(max_position)))
        
        # check if the pickup exceeds the first TS
        if self.ts_line is None or self.ts_line.is_empty or self.tempo_line is None or self.tempo_line.is_empty:
            raise Exception('Time Signature and Tempo sequences must be non-empty for time conversions.')
        if pickup.duration >= self.ts_line.event(0).object.beats_per_measure * \
                self.ts_line.event(0).object.beat_duration.duration:
            raise Exception(
                'pickup exceeds timing based on first time signature {0}'.format(self.ts_line.event(0).object))
        
        self._build_uniform_element_list()
        self._build_lines()
        self._build_search_trees()
        
        self.__max_time = self.position_to_actual_time(self.max_position)
        
    @property
    def max_position(self):
        return self.__max_position
    
    @property
    def pickup(self):
        return self.__pickup
        
    @property
    def max_time(self):
        return self.__max_time
        
    def _build_uniform_element_list(self):
        self.element_list = [Element(x.object, x.time) for x in self.tempo_line.sequence_list] + \
                            [Element(x.object, x.time) for x in self.ts_line.sequence_list]
        self.element_list.sort(key=lambda p: p.position)
        
    def _build_lines(self):
        """
        Compute the actual time for the tempo and time signature elements.
        """
        current_ts = None
        current_tempo = None
        current_at = 0
        last_position = None
        
        for element in self.element_list:
            if current_ts and current_tempo:
                translated_tempo = current_tempo.effective_tempo(current_ts.beat_duration)
                current_at += (element.position - last_position).duration / \
                              (current_ts.beat_duration.duration * translated_tempo) * 60 * 1000
                element.position_time = current_at
                
            if element.is_tempo:
                current_tempo = element.element
            else:
                current_ts = element.element
            last_position = element.position
            
    def _build_search_trees(self):
        ts_mt_list = []
        ts_time_list = []
        tempo_mt_list = []
        tempo_time_list = []
        
        for element in self.element_list:
            if element.is_tempo:
                tempo_mt_list.append((element.position, element.element))
                tempo_time_list.append((element.position_time, element.element))
            else:
                ts_mt_list.append((element.position, element.element))
                ts_time_list.append((element.position_time, element.element))
                
        self.ts_mt_map = OrderedMap(ts_mt_list)    # whole note time --> TimeSignature
        self.ts_time_map = OrderedMap(ts_time_list)   # actual time --> TimeSignature

        self.tempo_mt_map = OrderedMap(tempo_mt_list)  # whole note time to Tempo
        self.tempo_time_map = OrderedMap(tempo_time_list)   # actual time to Tempo
        
        # Build an ordered map, mapping BeatPosition --> time signature.
        ts_bp_list = []
        (position, ts) = ts_mt_list[0]
        prior_pickup = 0
        measure_tally = 0
        if self.pickup.duration > 0:
            num_beats = self.pickup.duration / ts.beat_duration.duration
            ts_bp_list.append((BeatPosition(0, ts.beats_per_measure - num_beats), ts))
            prior_pickup = num_beats
        else:
            ts_bp_list.append((BeatPosition(0, Fraction(0, 1)), ts))           
        
        for i in range(1, len(ts_mt_list)):
            (position, ts) = ts_mt_list[i]
            (prior_position, prior_ts) = ts_mt_list[i - 1]
            num_beats = (position - prior_position).duration / prior_ts.beat_duration.duration - prior_pickup
            num_measures = int(num_beats / prior_ts.beats_per_measure) + (1 if prior_pickup > 0 else 0)
            measure_tally += num_measures
            prior_pickup = 0
            ts_bp_list.append((BeatPosition(measure_tally, 0), ts))
        self.ts_bp_map = OrderedMap(ts_bp_list)    # beat position --> TimeSignature    

    def position_to_actual_time(self, position):
        """
        Convert a whole time position to it's actual time (in ms) from the beginning.
        
        Args:
          position: a Position in whole time.
        Returns:
          The actual time in ms for the position relative to the beginning.
          
        Note: if the position exceeds max_position, we use max_position
        """
        (tempo_mt_floor, tempo_element) = self.tempo_mt_map.floor_entry(position)
        tempo_time = self.tempo_time_map.reverse_get(tempo_element)
        
        (ts_mt_floor, ts_element) = self.ts_mt_map.floor_entry(position)
        ts_time = self.ts_time_map.reverse_get(ts_element)
        
        start_mt = max(tempo_mt_floor, ts_mt_floor)
        start_time = max(tempo_time, ts_time)
        # at this point, we have:
        #  start_mt: a whole time to start from
        #  start_time: the actual time to start from
        #  tempo_element: the current Tempo
        #  ts_element: the current TimeSignature
        
        delta_mt = min(position, self.max_position) - start_mt
        translated_tempo = tempo_element.effective_tempo(ts_element.beat_duration)
        # time = music_time / (beat_duration * tempo)
        delta_time = (delta_mt.duration / (ts_element.beat_duration.duration * translated_tempo)
                      if delta_mt > 0 else 0) * 60 * 1000
      
        return start_time + delta_time
     
    def actual_time_to_position(self, actual_time):  
        """
        Convert from an actual time (ms) position to a whole time Position
        
        Args:
          actual_time: the actual time (ms) of a position in the music
        Returns:
          the Position corresponding to the actual time.
          
        Note: if actual_time exceeds max_time, we use max_time.
        """
        (tempo_time_floor, tempo_element) = self.tempo_time_map.floor_entry(actual_time)
        tempo_mt = self.tempo_mt_map.reverse_get(tempo_element)
        (ts_time_floor, ts_element) = self.ts_time_map.floor_entry(actual_time)
        ts_mt = self.ts_mt_map.reverse_get(ts_element)
        
        start_mt = max(tempo_mt, ts_mt)
        start_time = max(tempo_time_floor, ts_time_floor)
        # at this point, we have:
        #  start_mt: a whole note time to start from
        #  start_time: the actual time to measure from
        #  tempo_element: the current Tempo
        #  ts_element: the current TimeSignature
        
        delta_time = min(actual_time, self.max_time) - start_time
        if not isinstance(delta_time, Fraction):
            delta_time = Fraction.from_float(delta_time)
        # musicTime = time * tempo * beat_duration
        # Translate tempo using the time signature beat.
        translated_tempo = tempo_element.effective_tempo(ts_element.beat_duration)
        delta_mt = (delta_time * translated_tempo * ts_element.beat_duration.duration / (60 * 1000)) \
            if delta_time > 0 else 0
        
        return start_mt + delta_mt
    
    def bp_to_position(self, beat_position):
        """
        Method to convert a beat position to a whole note time position.
        
        Args:
          beat_position: BeatPosition object given measure, beat number
        Returns:
          the whole note time position for beat_position.
          
        Exceptions:
          for improper beat_position values
        """
        (beginning_bp, ts_element) = self.ts_bp_map.floor_entry(beat_position)
        if beat_position.beat_number >= ts_element.beats_per_measure:
            raise Exception(
                'Illegal beat asked for {0}, ts has 0-{1} beats per measure.'.format(beat_position.beat_number,
                                                                                     ts_element.beats_per_measure - 1))
        
        ts_mt_floor = self.ts_mt_map.reverse_get(ts_element)
        
        delta_mt = ((beat_position.measure_number - beginning_bp.measure_number) * ts_element.beats_per_measure +
                    beat_position.beat_number - beginning_bp.beat_number) * ts_element.beat_duration.duration
        return Position(ts_mt_floor.position + delta_mt)
    
    def position_to_bp(self, position):
        """
        Method to convert a whole note time position to a beat position
        
        Args:
          position: the whole note time position
        Returns:
          the BeatPosition corresponding to the given position
        """
        (ts_mt_floor, ts_element) = self.ts_mt_map.floor_entry(position)
        
        ts_bp = self.ts_bp_map.reverse_get(ts_element)
        
        num_beats = (position - ts_mt_floor).duration / ts_element.beat_duration.duration   # - prior_pickup.duration
        num_measures = int(num_beats / ts_element.beats_per_measure)   # + (1 if prior_pickup.duration > 0 else 0)
        residual_beats = num_beats - num_measures * ts_element.beats_per_measure
        
        # add the measures and beats  to ts_bp
        beats = ts_bp.beat_number + residual_beats
        measures = ts_bp.measure_number + num_measures
        if beats >= ts_element.beats_per_measure:
            beats -= ts_element.beats_per_measure
            measures += 1
                    
        return BeatPosition(measures, beats)