2 beam.cc -- implement Beam
4 source file of the GNU LilyPond music typesetter
6 (c) 1997--2008 Han-Wen Nienhuys <hanwen@xs4all.nl>
7 Jan Nieuwenhuizen <janneke@gnu.org>
13 - Determine auto knees based on positions if it's set by the user.
15 - the code is littered with * and / staff_space calls for
16 #'positions. Consider moving to real-world coordinates?
18 Problematic issue is user tweaks (user tweaks are in staff-coordinates.)
22 - Stems run to the Y-center of the beam.
24 - beam_translation is the offset between Y centers of the beam.
29 #include "beaming-pattern.hh"
30 #include "directional-element-interface.hh"
32 #include "international.hh"
33 #include "interval-set.hh"
35 #include "least-squares.hh"
38 #include "output-def.hh"
39 #include "pointer-group-interface.hh"
41 #include "staff-symbol-referencer.hh"
44 #include "grob-array.hh"
46 #if DEBUG_BEAM_SCORING
47 #include "text-interface.hh" // debug output.
48 #include "font-interface.hh" // debug output.
54 Beam_stem_segment::Beam_stem_segment ()
56 max_connect_ = 1000; // infinity
65 Beam_segment::Beam_segment ()
71 Beam::add_stem (Grob *me, Grob *s)
73 if (Stem::get_beam (s))
75 programming_error ("Stem already has beam");
79 Pointer_group_interface::add_grob (me, ly_symbol2scm ("stems"), s);
80 s->set_object ("beam", me->self_scm ());
81 add_bound_item (dynamic_cast<Spanner *> (me), dynamic_cast<Item *> (s));
85 Beam::get_thickness (Grob *me)
87 return robust_scm2double (me->get_property ("thickness"), 0)
88 * Staff_symbol_referencer::staff_space (me);
91 /* Return the translation between 2 adjoining beams. */
93 Beam::get_beam_translation (Grob *me)
95 int beam_count = get_beam_count (me);
96 Real staff_space = Staff_symbol_referencer::staff_space (me);
97 Real line = Staff_symbol_referencer::line_thickness (me);
98 Real thickness = get_thickness (me);
99 Real fract = robust_scm2double (me->get_property ("length-fraction"), 1.0);
101 Real beam_translation = beam_count < 4
102 ? (2 * staff_space + line - thickness) / 2.0
103 : (3 * staff_space + line - thickness) / 3.0;
105 return fract * beam_translation;
108 /* Maximum beam_count. */
110 Beam::get_beam_count (Grob *me)
114 extract_grob_set (me, "stems", stems);
115 for (vsize i = 0; i < stems.size (); i++)
117 Grob *stem = stems[i];
118 m = max (m, (Stem::beam_multiplicity (stem).length () + 1));
123 MAKE_SCHEME_CALLBACK (Beam, calc_normal_stems, 1);
125 Beam::calc_normal_stems (SCM smob)
127 Grob *me = unsmob_grob (smob);
129 extract_grob_set (me, "stems", stems);
130 SCM val = Grob_array::make_array ();
131 Grob_array *ga = unsmob_grob_array (val);
132 for (vsize i = 0; i < stems.size (); i++)
133 if (Stem::is_normal_stem (stems[i]))
139 MAKE_SCHEME_CALLBACK (Beam, calc_direction, 1);
141 Beam::calc_direction (SCM smob)
143 Grob *me = unsmob_grob (smob);
145 /* Beams with less than 2 two stems don't make much sense, but could happen
152 Direction dir = CENTER;
154 int count = normal_stem_count (me);
157 extract_grob_set (me, "stems", stems);
158 if (stems.size () == 0)
160 me->warning (_ ("removing beam with no stems"));
163 return SCM_UNSPECIFIED;
167 Grob *stem = first_normal_stem (me);
170 This happens for chord tremolos.
175 if (is_direction (stem->get_property_data ("direction")))
176 dir = to_dir (stem->get_property_data ("direction"));
178 dir = to_dir (stem->get_property ("default-direction"));
185 dir = get_default_dir (me);
187 consider_auto_knees (me);
192 set_stem_directions (me, dir);
195 return scm_from_int (dir);
200 /* We want a maximal number of shared beams, but if there is choice, we
201 * take the one that is closest to the end of the stem. This is for
213 position_with_maximal_common_beams (SCM left_beaming, SCM right_beaming,
217 Slice lslice = int_list_to_slice (scm_cdr (left_beaming));
221 for (int i = lslice[-left_dir];
222 (i - lslice[left_dir]) * left_dir <= 0; i += left_dir)
225 for (SCM s = scm_car (right_beaming); scm_is_pair (s); s = scm_cdr (s))
227 int k = -right_dir * scm_to_int (scm_car (s)) + i;
228 if (scm_c_memq (scm_from_int (k), left_beaming) != SCM_BOOL_F)
232 if (count >= best_count)
242 MAKE_SCHEME_CALLBACK (Beam, calc_beaming, 1)
244 Beam::calc_beaming (SCM smob)
246 Grob *me = unsmob_grob (smob);
248 extract_grob_set (me, "stems", stems);
251 last_int.set_empty ();
253 SCM last_beaming = scm_cons (SCM_EOL, scm_list_1 (scm_from_int (0)));
254 Direction last_dir = CENTER;
255 for (vsize i = 0; i < stems.size (); i++)
257 Grob *this_stem = stems[i];
258 SCM this_beaming = this_stem->get_property ("beaming");
260 Direction this_dir = get_grob_direction (this_stem);
261 if (scm_is_pair (last_beaming) && scm_is_pair (this_beaming))
263 int start_point = position_with_maximal_common_beams
264 (last_beaming, this_beaming,
265 last_dir ? last_dir : this_dir,
272 new_slice.set_empty ();
273 SCM s = index_get_cell (this_beaming, d);
274 for (; scm_is_pair (s); s = scm_cdr (s))
277 = start_point - this_dir * scm_to_int (scm_car (s));
279 new_slice.add_point (new_beam_pos);
280 scm_set_car_x (s, scm_from_int (new_beam_pos));
283 while (flip (&d) != LEFT);
285 if (!new_slice.is_empty ())
286 last_int = new_slice;
291 FIXME: what's this for?
293 SCM s = scm_cdr (this_beaming);
294 for (; scm_is_pair (s); s = scm_cdr (s))
296 int np = -this_dir * scm_to_int (scm_car (s));
297 scm_set_car_x (s, scm_from_int (np));
298 last_int.add_point (np);
302 if (scm_ilength (scm_cdr (this_beaming)) > 0)
304 last_beaming = this_beaming;
313 operator <(Beam_stem_segment const &a,
314 Beam_stem_segment const &b)
316 return a.rank_ < b.rank_;
319 typedef map<int, vector<Beam_stem_segment> > Position_stem_segments_map;
322 Beam::get_beam_segments (Grob *me_grob, Grob **common)
324 /* ugh, this has a side-effect that we need to ensure that
325 Stem #'beaming is correct */
326 (void) me_grob->get_property ("beaming");
328 Spanner *me = dynamic_cast<Spanner*> (me_grob);
330 extract_grob_set (me, "stems", stems);
331 Grob *commonx = common_refpoint_of_array (stems, me, X_AXIS);
333 commonx = me->get_bound (LEFT)->common_refpoint (commonx, X_AXIS);
334 commonx = me->get_bound (RIGHT)->common_refpoint (commonx, X_AXIS);
338 int gap_count = robust_scm2int (me->get_property ("gap-count"), 0);
339 Real gap_length = robust_scm2double (me->get_property ("gap"), 0.0);
341 Position_stem_segments_map stem_segments;
342 Real lt = me->layout ()->get_dimension (ly_symbol2scm ("line-thickness"));
345 for (vsize i = 0; i < stems.size (); i++)
347 Grob *stem = stems[i];
348 Real stem_width = robust_scm2double (stem->get_property ("thickness"), 1.0) * lt;
349 Real stem_x = stem->relative_coordinate (commonx, X_AXIS);
350 SCM beaming = stem->get_property ("beaming");
354 for (SCM s = index_get_cell (beaming, d);
355 scm_is_pair (s); s = scm_cdr (s))
357 if (!scm_is_integer (scm_car (s)))
360 int beam_rank = scm_to_int (scm_car (s));
361 ranks.add_point (beam_rank);
364 for (SCM s = index_get_cell (beaming, d);
365 scm_is_pair (s); s = scm_cdr (s))
367 if (!scm_is_integer (scm_car (s)))
370 int beam_rank = scm_to_int (scm_car (s));
371 Beam_stem_segment seg;
373 seg.stem_x_ = stem_x;
374 seg.rank_ = 2 * i + (d+1)/2;
375 seg.width_ = stem_width;
378 seg.max_connect_ = robust_scm2int (stem->get_property ("max-beam-connect"), 1000);
380 Direction stem_dir = get_grob_direction (stem);
383 = (stem_dir * beam_rank < (stem_dir * ranks[-stem_dir] + gap_count));
384 stem_segments[beam_rank].push_back (seg);
387 while (flip (&d) != LEFT);
390 Drul_array<Real> break_overshoot
391 = robust_scm2drul (me->get_property ("break-overshoot"),
392 Drul_array<Real> (-0.5, 0.0));
394 vector<Beam_segment> segments;
395 for (Position_stem_segments_map::const_iterator i (stem_segments.begin ());
396 i != stem_segments.end (); i++)
398 vector<Beam_stem_segment> segs = (*i).second;
399 vector_sort (segs, less<Beam_stem_segment> ());
401 Beam_segment current;
403 int vertical_count = (*i).first;
404 for (vsize j = 0; j < segs.size (); j++)
407 event_dir == LEFT: left edge of a beamsegment.
409 Direction event_dir = LEFT;
412 bool on_line_bound = (segs[j].dir_ == LEFT) ? segs[j].stem_index_ == 0
413 : segs[j].stem_index_ == stems.size() - 1;
414 bool on_beam_bound = (event_dir == LEFT) ? j == 0 :
415 j == segs.size () - 1;
416 bool inside_stem = (event_dir == LEFT)
417 ? segs[j].stem_index_ > 0
418 : segs[j].stem_index_ + 1 < stems.size () ;
420 bool event = on_beam_bound
421 || abs (segs[j].rank_ - segs[j+event_dir].rank_) > 1
422 || (abs (vertical_count) >= segs[j].max_connect_
423 || abs (vertical_count) >= segs[j + event_dir].max_connect_);
428 current.vertical_count_ = vertical_count;
429 current.horizontal_[event_dir] = segs[j].stem_x_;
430 if (segs[j].dir_ == event_dir)
433 && me->get_bound (event_dir)->break_status_dir ())
435 current.horizontal_[event_dir]
436 = (robust_relative_extent (me->get_bound (event_dir),
437 commonx, X_AXIS)[RIGHT]
438 + event_dir * break_overshoot[event_dir]);
442 Real notehead_width =
443 Stem::duration_log (segs[j].stem_) == 1
450 Grob *neighbor_stem = stems[segs[j].stem_index_ + event_dir];
452 = neighbor_stem->relative_coordinate (commonx, X_AXIS);
454 notehead_width = min (notehead_width,
455 fabs (neighbor_stem_x - segs[j].stem_x_)/2.5);
457 current.horizontal_[event_dir] += event_dir * notehead_width;
462 current.horizontal_[event_dir] += event_dir * segs[j].width_/2;
465 current.horizontal_[event_dir] -= event_dir * gap_length;
467 if (Stem::is_invisible (segs[j].stem_))
470 Need to do this in case of whole notes. We don't want the
471 heads to collide with the beams.
473 extract_grob_set (segs[j].stem_, "note-heads", heads);
475 for (vsize k = 0; k < heads.size (); k ++)
476 current.horizontal_[event_dir]
477 = event_dir * min (event_dir * current.horizontal_[event_dir],
480 * heads[k]->extent (commonx,
481 X_AXIS)[-event_dir]);
486 if (event_dir == RIGHT)
488 segments.push_back (current);
489 current = Beam_segment ();
492 while (flip (&event_dir) != LEFT);
500 MAKE_SCHEME_CALLBACK (Beam, print, 1);
502 Beam::print (SCM grob)
504 Spanner *me = unsmob_spanner (grob);
506 vector<Beam_segment> segments = get_beam_segments (me, &commonx);
509 if (normal_stem_count (me))
511 span[LEFT] = first_normal_stem (me)->relative_coordinate (commonx, X_AXIS);
512 span[RIGHT] = last_normal_stem (me)->relative_coordinate (commonx, X_AXIS);
516 extract_grob_set (me, "stems", stems);
517 span[LEFT] = stems[0]->relative_coordinate (commonx, X_AXIS);
518 span[RIGHT] = stems.back ()->relative_coordinate (commonx, X_AXIS);
521 Real blot = me->layout ()->get_dimension (ly_symbol2scm ("blot-diameter"));
523 SCM posns = me->get_property ("quantized-positions");
525 if (!is_number_pair (posns))
527 programming_error ("no beam positions?");
528 pos = Interval (0, 0);
531 pos = ly_scm2realdrul (posns);
533 scale_drul (&pos, Staff_symbol_referencer::staff_space (me));
535 Real dy = pos[RIGHT] - pos[LEFT];
536 Real slope = (dy && span.length ()) ? dy / span.length () : 0;
538 Real thick = get_thickness (me);
539 Real beam_dy = get_beam_translation (me);
541 Direction feather_dir = to_dir (me->get_property ("grow-direction"));
544 for (vsize i = 0; i < segments.size (); i ++)
546 Real local_slope = slope;
549 local_slope += feather_dir * segments[i].vertical_count_ * beam_dy / span.length ();
552 Stencil b = Lookup::beam (local_slope, segments[i].horizontal_.length (), thick, blot);
554 b.translate_axis (segments[i].horizontal_[LEFT], X_AXIS);
556 b.translate_axis (local_slope
557 * (segments[i].horizontal_[LEFT] - span.linear_combination (feather_dir))
558 + pos.linear_combination (feather_dir)
559 + beam_dy * segments[i].vertical_count_, Y_AXIS);
560 the_beam.add_stencil (b);
563 #if (DEBUG_BEAM_SCORING)
564 SCM annotation = me->get_property ("annotation");
565 if (!scm_is_string (annotation))
567 SCM debug = me->layout ()->lookup_variable (ly_symbol2scm ("debug-beam-scoring"));
568 if (to_boolean (debug))
569 annotation = me->get_property ("quant-score");
572 if (scm_is_string (annotation))
574 extract_grob_set (me, "stems", stems);
577 This code prints the demerits for each beam. Perhaps this
578 should be switchable for those who want to twiddle with the
582 SCM properties = Font_interface::text_font_alist_chain (me);
584 Direction stem_dir = stems.size () ? to_dir (stems[0]->get_property ("direction")) : UP;
586 Stencil score = *unsmob_stencil (Text_interface::interpret_markup
587 (me->layout ()->self_scm (), properties, annotation));
589 if (!score.is_empty ())
591 score.translate_axis (me->relative_coordinate(commonx, X_AXIS), X_AXIS);
592 the_beam.add_at_edge (Y_AXIS, stem_dir, score, 1.0);
597 the_beam.translate_axis (-me->relative_coordinate (commonx, X_AXIS), X_AXIS);
598 return the_beam.smobbed_copy ();
602 Beam::get_default_dir (Grob *me)
604 extract_grob_set (me, "stems", stems);
606 Drul_array<Real> extremes (0.0, 0.0);
607 for (iterof (s, stems); s != stems.end (); s++)
609 Interval positions = Stem::head_positions (*s);
613 if (sign (positions[d]) == d)
614 extremes[d] = d * max (d * positions[d], d * extremes[d]);
616 while (flip (&d) != DOWN);
619 Drul_array<int> total (0, 0);
620 Drul_array<int> count (0, 0);
622 bool force_dir = false;
623 for (vsize i = 0; i < stems.size (); i++)
626 Direction stem_dir = CENTER;
627 SCM stem_dir_scm = s->get_property_data ("direction");
628 if (is_direction (stem_dir_scm))
630 stem_dir = to_dir (stem_dir_scm);
634 stem_dir = to_dir (s->get_property ("default-direction"));
637 stem_dir = to_dir (s->get_property ("neutral-direction"));
642 total[stem_dir] += max (int (- stem_dir * Stem::head_positions (s) [-stem_dir]), 0);
649 if (abs (extremes[UP]) > -extremes[DOWN])
651 else if (extremes[UP] < -extremes[DOWN])
655 Direction dir = CENTER;
656 Direction d = CENTER;
657 if ((d = (Direction) sign (count[UP] - count[DOWN])))
661 && (d = (Direction) sign (total[UP] / count[UP] - total[DOWN]/count[DOWN])))
663 else if ((d = (Direction) sign (total[UP] - total[DOWN])))
666 dir = to_dir (me->get_property ("neutral-direction"));
671 /* Set all stems with non-forced direction to beam direction.
672 Urg: non-forced should become `without/with unforced' direction,
673 once stem gets cleaned-up. */
675 Beam::set_stem_directions (Grob *me, Direction d)
677 extract_grob_set (me, "stems", stems);
679 for (vsize i = 0; i < stems.size (); i++)
683 SCM forcedir = s->get_property_data ("direction");
684 if (!to_dir (forcedir))
685 set_grob_direction (s, d);
690 Only try horizontal beams for knees. No reliable detection of
691 anything else is possible here, since we don't know funky-beaming
692 settings, or X-distances (slopes!) People that want sloped
693 knee-beams, should set the directions manually.
698 this routine should take into account the stemlength scoring
699 of a possible knee/nonknee beam.
702 Beam::consider_auto_knees (Grob *me)
704 SCM scm = me->get_property ("auto-knee-gap");
705 if (!scm_is_number (scm))
712 extract_grob_set (me, "normal-stems", stems);
714 Grob *common = common_refpoint_of_array (stems, me, Y_AXIS);
715 Real staff_space = Staff_symbol_referencer::staff_space (me);
717 vector<Interval> head_extents_array;
718 for (vsize i = 0; i < stems.size (); i++)
720 Grob *stem = stems[i];
722 Interval head_extents = Stem::head_positions (stem);
723 if (!head_extents.is_empty ())
725 head_extents[LEFT] += -1;
726 head_extents[RIGHT] += 1;
727 head_extents *= staff_space * 0.5;
730 We could subtract beam Y position, but this routine only
731 sets stem directions, a constant shift does not have an
734 head_extents += stem->pure_relative_y_coordinate (common, 0, INT_MAX);
736 if (to_dir (stem->get_property_data ("direction")))
738 Direction stemdir = to_dir (stem->get_property ("direction"));
739 head_extents[-stemdir] = -stemdir * infinity_f;
742 head_extents_array.push_back (head_extents);
744 gaps.remove_interval (head_extents);
748 Real max_gap_len = 0.0;
750 for (vsize i = gaps.allowed_regions_.size () -1; i != VPOS ;i--)
752 Interval gap = gaps.allowed_regions_[i];
755 the outer gaps are not knees.
757 if (isinf (gap[LEFT]) || isinf (gap[RIGHT]))
760 if (gap.length () >= max_gap_len)
762 max_gap_len = gap.length ();
767 Real beam_translation = get_beam_translation (me);
768 Real beam_thickness = Beam::get_thickness (me);
769 int beam_count = Beam::get_beam_count (me);
770 Real height_of_beams = beam_thickness / 2
771 + (beam_count - 1) * beam_translation;
772 Real threshold = scm_to_double (scm) + height_of_beams;
774 if (max_gap_len > threshold)
777 for (vsize i = 0; i < stems.size (); i++)
779 Grob *stem = stems[i];
780 Interval head_extents = head_extents_array[j++];
782 Direction d = (head_extents.center () < max_gap.center ())
785 stem->set_property ("direction", scm_from_int (d));
787 head_extents.intersect (max_gap);
788 assert (head_extents.is_empty () || head_extents.length () < 1e-6);
793 /* Set stem's shorten property if unset.
796 take some y-position (chord/beam/nearest?) into account
797 scmify forced-fraction
799 This is done in beam because the shorten has to be uniform over the
806 set_minimum_dy (Grob *me, Real *dy)
811 If dy is smaller than the smallest quant, we
812 get absurd direction-sign penalties.
815 Real ss = Staff_symbol_referencer::staff_space (me);
816 Real thickness = Beam::get_thickness (me) / ss;
817 Real slt = Staff_symbol_referencer::line_thickness (me) / ss;
818 Real sit = (thickness - slt) / 2;
820 Real hang = 1.0 - (thickness - slt) / 2;
822 *dy = sign (*dy) * max (fabs (*dy),
823 min (min (sit, inter), hang));
829 MAKE_SCHEME_CALLBACK (Beam, calc_stem_shorten, 1)
831 Beam::calc_stem_shorten (SCM smob)
833 Grob *me = unsmob_grob (smob);
836 shortening looks silly for x staff beams
839 return scm_from_int (0);
841 Real forced_fraction = 1.0 * forced_stem_count (me)
842 / normal_stem_count (me);
844 int beam_count = get_beam_count (me);
846 SCM shorten_list = me->get_property ("beamed-stem-shorten");
847 if (shorten_list == SCM_EOL)
848 return scm_from_int (0);
850 Real staff_space = Staff_symbol_referencer::staff_space (me);
853 = robust_list_ref (beam_count -1, shorten_list);
854 Real shorten = scm_to_double (shorten_elt) * staff_space;
856 shorten *= forced_fraction;
860 return scm_from_double (shorten);
862 return scm_from_double (0.0);
867 Beam::no_visible_stem_positions (Grob *me, Interval default_value)
869 extract_grob_set (me, "stems", stems);
871 return default_value;
873 Interval head_positions;
875 for (vsize i = 0; i < stems.size(); i++)
877 head_positions.unite (Stem::head_positions (stems[i]));
878 multiplicity.unite (Stem::beam_multiplicity (stems[i]));
881 Direction dir = get_grob_direction (me);
882 Real y = head_positions[dir]
883 * 0.5 * Staff_symbol_referencer::staff_space (me)
884 + dir * get_beam_translation (me) * (multiplicity.length () + 1);
886 y /= Staff_symbol_referencer::staff_space (me);
887 return Interval (y,y);
892 Compute a first approximation to the beam slope.
894 MAKE_SCHEME_CALLBACK (Beam, calc_least_squares_positions, 2);
896 Beam::calc_least_squares_positions (SCM smob, SCM posns)
900 Grob *me = unsmob_grob (smob);
902 int count = normal_stem_count (me);
905 return ly_interval2scm (no_visible_stem_positions (me, pos));
907 vector<Real> x_posns;
908 extract_grob_set (me, "normal-stems", stems);
909 Grob *commonx = common_refpoint_of_array (stems, me, X_AXIS);
910 Grob *commony = common_refpoint_of_array (stems, me, Y_AXIS);
912 Real my_y = me->relative_coordinate (commony, Y_AXIS);
914 Grob *fvs = first_normal_stem (me);
915 Grob *lvs = last_normal_stem (me);
917 Interval ideal (Stem::get_stem_info (fvs).ideal_y_
918 + fvs->relative_coordinate (commony, Y_AXIS) - my_y,
919 Stem::get_stem_info (lvs).ideal_y_
920 + lvs->relative_coordinate (commony, Y_AXIS) - my_y);
922 Real x0 = first_normal_stem (me)->relative_coordinate (commonx, X_AXIS);
923 for (vsize i = 0; i < stems.size (); i++)
927 Real x = s->relative_coordinate (commonx, X_AXIS) - x0;
928 x_posns.push_back (x);
930 Real dx = last_normal_stem (me)->relative_coordinate (commonx, X_AXIS) - x0;
938 Interval chord (Stem::chord_start_y (stems[0]),
939 Stem::chord_start_y (stems.back ()));
941 /* Simple beams (2 stems) on middle line should be allowed to be
944 However, if both stems reach middle line,
945 ideal[LEFT] == ideal[RIGHT] and ideal.delta () == 0.
947 For that case, we apply artificial slope */
948 if (!ideal[LEFT] && chord.delta () && count == 2)
951 Direction d = (Direction) (sign (chord.delta ()) * UP);
952 pos[d] = get_thickness (me) / 2;
959 For broken beams this doesn't work well. In this case, the
960 slope esp. of the first part of a broken beam should predict
961 where the second part goes.
963 ldy = pos[RIGHT] - pos[LEFT];
967 vector<Offset> ideals;
968 for (vsize i = 0; i < stems.size (); i++)
971 ideals.push_back (Offset (x_posns[i],
972 Stem::get_stem_info (s).ideal_y_
973 + s->relative_coordinate (commony, Y_AXIS)
977 minimise_least_squares (&slope, &y, ideals);
981 set_minimum_dy (me, &dy);
984 pos = Interval (y, (y + dy));
988 "position" is relative to the staff.
990 scale_drul (&pos, 1 / Staff_symbol_referencer::staff_space (me));
992 me->set_property ("least-squares-dy", scm_from_double (ldy));
993 return ly_interval2scm (pos);
997 We can't combine with previous function, since check concave and
998 slope damping comes first.
1000 TODO: we should use the concaveness to control the amount of damping
1003 MAKE_SCHEME_CALLBACK (Beam, shift_region_to_valid, 2);
1005 Beam::shift_region_to_valid (SCM grob, SCM posns)
1007 Grob *me = unsmob_grob (grob);
1011 vector<Real> x_posns;
1012 extract_grob_set (me, "stems", stems);
1013 Grob *commonx = common_refpoint_of_array (stems, me, X_AXIS);
1014 Grob *commony = common_refpoint_of_array (stems, me, Y_AXIS);
1016 Grob *fvs = first_normal_stem (me);
1021 Real x0 = fvs->relative_coordinate (commonx, X_AXIS);
1022 for (vsize i = 0; i < stems.size (); i++)
1026 Real x = s->relative_coordinate (commonx, X_AXIS) - x0;
1027 x_posns.push_back (x);
1030 Grob *lvs = last_normal_stem (me);
1034 Real dx = lvs->relative_coordinate (commonx, X_AXIS) - x0;
1036 Drul_array<Real> pos = ly_scm2interval (posns);
1038 scale_drul (&pos, Staff_symbol_referencer::staff_space (me));
1040 Real dy = pos[RIGHT] - pos[LEFT];
1042 Real slope = dx ? (dy / dx) : 0.0;
1045 Shift the positions so that we have a chance of finding good
1046 quants (i.e. no short stem failures.)
1048 Interval feasible_left_point;
1049 feasible_left_point.set_full ();
1050 for (vsize i = 0; i < stems.size (); i++)
1053 if (Stem::is_invisible (s))
1056 Direction d = get_grob_direction (s);
1059 = Stem::get_stem_info (s).shortest_y_
1060 - slope * x_posns [i];
1063 left_y is now relative to the stem S. We want relative to
1064 ourselves, so translate:
1067 += + s->relative_coordinate (commony, Y_AXIS)
1068 - me->relative_coordinate (commony, Y_AXIS);
1074 feasible_left_point.intersect (flp);
1077 if (feasible_left_point.is_empty ())
1078 warning (_ ("no viable initial configuration found: may not find good beam slope"));
1079 else if (!feasible_left_point.contains (y))
1081 const int REGION_SIZE = 2; // UGH UGH
1082 if (isinf (feasible_left_point[DOWN]))
1083 y = feasible_left_point[UP] - REGION_SIZE;
1084 else if (isinf (feasible_left_point[UP]))
1085 y = feasible_left_point[DOWN]+ REGION_SIZE;
1087 y = feasible_left_point.center ();
1090 pos = Drul_array<Real> (y, (y + dy));
1091 scale_drul (&pos, 1 / Staff_symbol_referencer::staff_space (me));
1093 return ly_interval2scm (pos);
1096 /* This neat trick is by Werner Lemberg,
1097 damped = tanh (slope)
1098 corresponds with some tables in [Wanske] CHECKME */
1099 MAKE_SCHEME_CALLBACK (Beam, slope_damping, 2);
1101 Beam::slope_damping (SCM smob, SCM posns)
1103 Grob *me = unsmob_grob (smob);
1104 Drul_array<Real> pos = ly_scm2interval (posns);
1106 if (normal_stem_count (me) <= 1)
1110 SCM s = me->get_property ("damping");
1111 Real damping = scm_to_double (s);
1112 Real concaveness = robust_scm2double (me->get_property ("concaveness"), 0.0);
1113 if (concaveness >= 10000)
1115 pos[LEFT] = pos[RIGHT];
1116 me->set_property ("least-squares-dy", scm_from_double (0));
1122 scale_drul (&pos, Staff_symbol_referencer::staff_space (me));
1124 Real dy = pos[RIGHT] - pos[LEFT];
1126 Grob *fvs = first_normal_stem (me);
1127 Grob *lvs = last_normal_stem (me);
1129 Grob *commonx = fvs->common_refpoint (lvs, X_AXIS);
1131 Real dx = last_normal_stem (me)->relative_coordinate (commonx, X_AXIS)
1132 - first_normal_stem (me)->relative_coordinate (commonx, X_AXIS);
1134 Real slope = dy && dx ? dy / dx : 0;
1136 slope = 0.6 * tanh (slope) / (damping + concaveness);
1138 Real damped_dy = slope * dx;
1140 set_minimum_dy (me, &damped_dy);
1142 pos[LEFT] += (dy - damped_dy) / 2;
1143 pos[RIGHT] -= (dy - damped_dy) / 2;
1145 scale_drul (&pos, 1 / Staff_symbol_referencer::staff_space (me));
1148 return ly_interval2scm (pos);
1152 Report slice containing the numbers that are both in (car BEAMING)
1156 where_are_the_whole_beams (SCM beaming)
1160 for (SCM s = scm_car (beaming); scm_is_pair (s); s = scm_cdr (s))
1162 if (scm_c_memq (scm_car (s), scm_cdr (beaming)) != SCM_BOOL_F)
1164 l.add_point (scm_to_int (scm_car (s)));
1170 /* Return the Y position of the stem-end, given the Y-left, Y-right
1171 in POS for stem S. This Y position is relative to S. */
1173 Beam::calc_stem_y (Grob *me, Grob *stem, Grob **common,
1174 Real xl, Real xr, Direction feather_dir,
1175 Drul_array<Real> pos, bool french)
1177 Real beam_translation = get_beam_translation (me);
1178 Direction stem_dir = get_grob_direction (stem);
1181 Real relx = dx ? (stem->relative_coordinate (common[X_AXIS], X_AXIS) - xl)/dx : 0;
1182 Real xdir = 2*relx-1;
1184 Real stem_y = linear_combination(pos, xdir);
1186 SCM beaming = stem->get_property ("beaming");
1188 Slice beam_slice (french
1189 ? where_are_the_whole_beams (beaming)
1190 : Stem::beam_multiplicity (stem));
1191 if (beam_slice.is_empty ())
1192 beam_slice = Slice (0,0);
1193 Interval beam_multiplicity(beam_slice[LEFT],
1197 feather dir = 1 , relx 0->1 : factor 0 -> 1
1198 feather dir = 0 , relx 0->1 : factor 1 -> 1
1199 feather dir = -1, relx 0->1 : factor 1 -> 0
1201 Real feather_factor = 1;
1202 if (feather_dir > 0)
1203 feather_factor = relx;
1204 else if (feather_dir < 0)
1205 feather_factor = 1 - relx;
1207 stem_y += feather_factor * beam_translation
1208 * beam_multiplicity[Direction(((french) ? DOWN : UP)*stem_dir)];
1209 Real id = me->relative_coordinate (common[Y_AXIS], Y_AXIS)
1210 - stem->relative_coordinate (common[Y_AXIS], Y_AXIS);
1216 Hmm. At this time, beam position and slope are determined. Maybe,
1217 stem directions and length should set to relative to the chord's
1218 position of the beam. */
1219 MAKE_SCHEME_CALLBACK (Beam, set_stem_lengths, 1);
1221 Beam::set_stem_lengths (SCM smob)
1223 Grob *me = unsmob_grob (smob);
1225 /* trigger callbacks. */
1226 (void) me->get_property ("direction");
1227 (void) me->get_property ("beaming");
1229 SCM posns = me->get_property ("positions");
1231 extract_grob_set (me, "stems", stems);
1236 for (int a = 2; a--;)
1237 common[a] = common_refpoint_of_array (stems, me, Axis (a));
1239 Drul_array<Real> pos = ly_scm2realdrul (posns);
1240 Real staff_space = Staff_symbol_referencer::staff_space (me);
1241 scale_drul (&pos, staff_space);
1245 if (robust_scm2int (me->get_property ("gap-count"), 0))
1248 thick = get_thickness (me);
1251 Grob *fvs = first_normal_stem (me);
1252 Grob *lvs = last_normal_stem (me);
1254 Real xl = fvs ? fvs->relative_coordinate (common[X_AXIS], X_AXIS) : 0.0;
1255 Real xr = lvs ? lvs->relative_coordinate (common[X_AXIS], X_AXIS) : 0.0;
1256 Direction feather_dir = to_dir (me->get_property ("grow-direction"));
1258 for (vsize i = 0; i < stems.size (); i++)
1262 bool french = to_boolean (s->get_property ("french-beaming"));
1263 Real stem_y = calc_stem_y (me, s, common,
1264 xl, xr, feather_dir,
1265 pos, french && s != lvs && s!= fvs);
1268 Make the stems go up to the end of the beam. This doesn't matter
1269 for normal beams, but for tremolo beams it looks silly otherwise.
1272 && !Stem::is_invisible (s))
1273 stem_y += thick * 0.5 * get_grob_direction (s);
1276 Do set_stemend for invisible stems too, so tuplet brackets
1277 have a reference point for sloping
1279 Stem::set_stemend (s, 2 * stem_y / staff_space);
1286 Beam::set_beaming (Grob *me, Beaming_pattern const *beaming)
1288 extract_grob_set (me, "stems", stems);
1291 for (vsize i = 0; i < stems.size (); i++)
1294 Don't overwrite user settings.
1298 Grob *stem = stems[i];
1299 SCM beaming_prop = stem->get_property ("beaming");
1300 if (beaming_prop == SCM_EOL
1301 || index_get_cell (beaming_prop, d) == SCM_EOL)
1303 int count = beaming->beamlet_count (i, d);
1305 && i + 1 < stems.size ()
1306 && Stem::is_invisible (stem))
1307 count = min (count, beaming->beamlet_count (i,-d));
1309 if ( ((i == 0 && d == LEFT)
1310 || (i == stems.size ()-1 && d == RIGHT))
1311 && stems.size () > 1
1312 && to_boolean (me->get_property ("clip-edges")))
1315 Stem::set_beaming (stem, count, d);
1318 while (flip (&d) != LEFT);
1323 Beam::forced_stem_count (Grob *me)
1325 extract_grob_set (me, "normal-stems", stems);
1328 for (vsize i = 0; i < stems.size (); i++)
1332 /* I can imagine counting those boundaries as a half forced stem,
1333 but let's count them full for now. */
1334 Direction defdir = to_dir (s->get_property ("default-direction"));
1336 if (abs (Stem::chord_start_y (s)) > 0.1
1338 && get_grob_direction (s) != defdir)
1345 Beam::normal_stem_count (Grob *me)
1347 extract_grob_set (me, "normal-stems", stems);
1348 return stems.size ();
1352 Beam::first_normal_stem (Grob *me)
1354 extract_grob_set (me, "normal-stems", stems);
1355 return stems.size () ? stems[0] : 0;
1359 Beam::last_normal_stem (Grob *me)
1361 extract_grob_set (me, "normal-stems", stems);
1362 return stems.size () ? stems.back () : 0;
1368 handle rest under beam (do_post: beams are calculated now)
1369 what about combination of collisions and rest under beam.
1373 rest -> stem -> beam -> interpolate_y_position ()
1375 MAKE_SCHEME_CALLBACK_WITH_OPTARGS (Beam, rest_collision_callback, 2, 1, "");
1377 Beam::rest_collision_callback (SCM smob, SCM prev_offset)
1379 Grob *rest = unsmob_grob (smob);
1380 if (scm_is_number (rest->get_property ("staff-position")))
1381 return scm_from_int (0);
1383 Real offset = robust_scm2double (prev_offset, 0.0);
1385 Grob *st = unsmob_grob (rest->get_object ("stem"));
1388 return scm_from_double (0.0);
1389 Grob *beam = unsmob_grob (stem->get_object ("beam"));
1391 || !Beam::has_interface (beam)
1392 || !Beam::normal_stem_count (beam))
1393 return scm_from_double (0.0);
1395 Drul_array<Real> pos (robust_scm2drul (beam->get_property ("positions"),
1396 Drul_array<Real> (0,0)));
1398 Real staff_space = Staff_symbol_referencer::staff_space (rest);
1400 scale_drul (&pos, staff_space);
1402 Real dy = pos[RIGHT] - pos[LEFT];
1404 Drul_array<Grob*> visible_stems (first_normal_stem (beam),
1405 last_normal_stem (beam));
1406 extract_grob_set (beam, "stems", stems);
1408 Grob *common = common_refpoint_of_array (stems, beam, X_AXIS);
1410 Real x0 = visible_stems[LEFT]->relative_coordinate (common, X_AXIS);
1411 Real dx = visible_stems[RIGHT]->relative_coordinate (common, X_AXIS) - x0;
1412 Real slope = dy && dx ? dy / dx : 0;
1414 Direction d = get_grob_direction (stem);
1415 Real stem_y = pos[LEFT]
1416 + (stem->relative_coordinate (common, X_AXIS) - x0) * slope;
1418 Real beam_translation = get_beam_translation (beam);
1419 Real beam_thickness = Beam::get_thickness (beam);
1422 TODO: this is not strictly correct for 16th knee beams.
1425 = Stem::beam_multiplicity (stem).length () + 1;
1427 Real height_of_my_beams = beam_thickness / 2
1428 + (beam_count - 1) * beam_translation;
1429 Real beam_y = stem_y - d * height_of_my_beams;
1431 Grob *common_y = rest->common_refpoint (beam, Y_AXIS);
1434 TODO: this is dubious, because this call needs the info we're
1435 computing right now.
1437 Interval rest_extent = rest->extent (common_y, Y_AXIS);
1438 rest_extent.translate (offset);
1440 Real rest_dim = rest_extent[d];
1441 Real minimum_distance
1442 = staff_space * (robust_scm2double (stem->get_property ("stemlet-length"), 0.0)
1443 + robust_scm2double (rest->get_property ("minimum-distance"), 0.0));
1445 Real shift = d * min (d * (beam_y - d * minimum_distance - rest_dim), 0.0);
1447 shift /= staff_space;
1448 Real rad = Staff_symbol_referencer::line_count (rest) * staff_space / 2;
1450 /* Always move discretely by half spaces */
1451 shift = ceil (fabs (shift * 2.0)) / 2.0 * sign (shift);
1453 /* Inside staff, move by whole spaces*/
1454 if ((rest_extent[d] + staff_space * shift) * d
1456 || (rest_extent[-d] + staff_space * shift) * -d
1458 shift = ceil (fabs (shift)) * sign (shift);
1460 return scm_from_double (offset + staff_space * shift);
1464 Beam::is_knee (Grob *me)
1466 SCM k = me->get_property ("knee");
1467 if (scm_is_bool (k))
1468 return ly_scm2bool (k);
1472 extract_grob_set (me, "stems", stems);
1473 for (vsize i = stems.size (); i--;)
1475 Direction dir = get_grob_direction (stems[i]);
1484 me->set_property ("knee", ly_bool2scm (knee));
1490 Beam::is_cross_staff (Grob *me)
1492 extract_grob_set (me, "stems", stems);
1493 Grob *staff_symbol = Staff_symbol_referencer::get_staff_symbol (me);
1494 for (vsize i = 0; i < stems.size (); i++)
1495 if (Staff_symbol_referencer::get_staff_symbol (stems[i]) != staff_symbol)
1500 MAKE_SCHEME_CALLBACK (Beam, calc_cross_staff, 1)
1502 Beam::calc_cross_staff (SCM smob)
1504 return scm_from_bool (is_cross_staff (unsmob_grob (smob)));
1508 Beam::get_direction_beam_count (Grob *me, Direction d)
1510 extract_grob_set (me, "stems", stems);
1513 for (vsize i = stems.size (); i--;)
1516 Should we take invisible stems into account?
1518 if (get_grob_direction (stems[i]) == d)
1519 bc = max (bc, (Stem::beam_multiplicity (stems[i]).length () + 1));
1525 ADD_INTERFACE (Beam,
1528 "The @code{thickness} property is the weight of beams,"
1529 " measured in staffspace. The @code{direction} property is"
1530 " not user-serviceable. Use the @code{direction} property"
1531 " of @code{Stem} instead.",
1536 "beamed-stem-shorten "
1551 "neutral-direction "
1555 "quantized-positions "