/*
This file is part of LilyPond, the GNU music typesetter.
- Copyright (C) 1997--2011 Han-Wen Nienhuys <hanwen@xs4all.nl>
+ Copyright (C) 1997--2015 Han-Wen Nienhuys <hanwen@xs4all.nl>
Jan Nieuwenhuizen <janneke@gnu.org>
LilyPond is free software: you can redistribute it and/or modify
#include "beam.hh"
+#include "axis-group-interface.hh"
#include "align-interface.hh"
#include "beam-scoring-problem.hh"
#include "beaming-pattern.hh"
Real beam_thickness = get_beam_thickness (me);
Real fract = robust_scm2double (me->get_property ("length-fraction"), 1.0);
- Real beam_translation = beam_count < 4
- ? (2 * staff_space + line - beam_thickness) / 2.0
- : (3 * staff_space + line - beam_thickness) / 3.0;
-
- return fract * beam_translation;
+ /*
+ if fract != 1.0, as is the case for grace notes, we want the gap
+ to decrease too. To achieve this, we divide the thickness by
+ fract */
+ return (beam_count < 4
+ ? (2 * staff_space * fract + line * fract - beam_thickness) / 2.0
+ : (3 * staff_space * fract + line * fract - beam_thickness) / 3.0);
}
/* Maximum beam_count. */
SCM
Beam::calc_normal_stems (SCM smob)
{
- Grob *me = unsmob_grob (smob);
+ Grob *me = unsmob<Grob> (smob);
extract_grob_set (me, "stems", stems);
SCM val = Grob_array::make_array ();
- Grob_array *ga = unsmob_grob_array (val);
+ Grob_array *ga = unsmob<Grob_array> (val);
for (vsize i = 0; i < stems.size (); i++)
if (Stem::is_normal_stem (stems[i]))
ga->add (stems[i]);
SCM
Beam::calc_direction (SCM smob)
{
- Grob *me = unsmob_grob (smob);
+ Grob *me = unsmob<Grob> (smob);
/* Beams with less than 2 two stems don't make much sense, but could happen
when you do
dir = to_dir (stem->get_property_data ("direction"));
else
dir = to_dir (stem->get_property ("default-direction"));
+
+ extract_grob_set (stem, "note-heads", heads);
+ /* default position of Kievan heads with beams is down
+ placing this here avoids warnings downstream */
+ if (heads.size())
+ {
+ if (scm_is_eq (heads[0]->get_property ("style"),
+ ly_symbol2scm ("kievan")))
+ {
+ if (dir == CENTER)
+ dir = DOWN;
+ }
+ }
}
}
for (SCM s = scm_car (right_beaming); scm_is_pair (s); s = scm_cdr (s))
{
int k = -right_dir * scm_to_int (scm_car (s)) + i;
- if (scm_c_memq (scm_from_int (k), left_beaming) != SCM_BOOL_F)
+ if (scm_is_true (ly_memv (scm_from_int (k), left_beaming)))
count++;
}
SCM
Beam::calc_beaming (SCM smob)
{
- Grob *me = unsmob_grob (smob);
+ Grob *me = unsmob<Grob> (smob);
extract_grob_set (me, "stems", stems);
last_dir ? last_dir : this_dir,
this_dir);
- Direction d = LEFT;
Slice new_slice;
- do
+ for (LEFT_and_RIGHT (d))
{
new_slice.set_empty ();
SCM s = index_get_cell (this_beaming, d);
scm_set_car_x (s, scm_from_int (new_beam_pos));
}
}
- while (flip (&d) != LEFT);
if (!new_slice.is_empty ())
last_int = new_slice;
typedef map<int, vector<Beam_stem_segment> > Position_stem_segments_map;
-// TODO - should store result in a property?
-vector<Beam_segment>
-Beam::get_beam_segments (Grob *me_grob, Grob **common)
+MAKE_SCHEME_CALLBACK (Beam, calc_beam_segments, 1);
+SCM
+Beam::calc_beam_segments (SCM smob)
{
/* ugh, this has a side-effect that we need to ensure that
Stem #'beaming is correct */
+ Grob *me_grob = unsmob<Grob> (smob);
(void) me_grob->get_property ("beaming");
Spanner *me = dynamic_cast<Spanner *> (me_grob);
extract_grob_set (me, "stems", stems);
- Grob *commonx = common_refpoint_of_array (stems, me, X_AXIS);
-
- commonx = me->get_bound (LEFT)->common_refpoint (commonx, X_AXIS);
- commonx = me->get_bound (RIGHT)->common_refpoint (commonx, X_AXIS);
- *common = commonx;
+ Grob *commonx = common_refpoint_of_array (stems, me, X_AXIS);
+ for (LEFT_and_RIGHT (d))
+ commonx = me->get_bound (d)->common_refpoint (commonx, X_AXIS);
int gap_count = robust_scm2int (me->get_property ("gap-count"), 0);
Real gap_length = robust_scm2double (me->get_property ("gap"), 0.0);
Real stem_width = robust_scm2double (stem->get_property ("thickness"), 1.0) * lt;
Real stem_x = stem->relative_coordinate (commonx, X_AXIS);
SCM beaming = stem->get_property ("beaming");
- Direction d = LEFT;
- do
+
+ for (LEFT_and_RIGHT (d))
{
// Find the maximum and minimum beam ranks.
// Given that RANKS is never reset to empty, the interval will always be
stem_segments[beam_rank].push_back (seg);
}
}
- while (flip (&d) != LEFT);
}
Drul_array<Real> break_overshoot
// we are currently looking at (ie. if segs[j].dir_ == event_dir then we
// are looking at that edge of the beam segment that is furthest from its
// stem).
- Direction event_dir = LEFT;
Beam_stem_segment const &seg = segs[j];
- do
+ for (LEFT_and_RIGHT (event_dir))
{
Beam_stem_segment const &neighbor_seg = segs[j + event_dir];
// TODO: make names clearer? --jneem
|| abs (vertical_count) >= neighbor_seg.max_connect_);
if (!event)
- // Then this edge of the current segment is irrelevent because it will
+ // Then this edge of the current segment is irrelevant because it will
// be connected with the next segment in the event_dir direction.
+ // If we skip the left edge here, the right edge of
+ // the previous segment has already been skipped since
+ // the conditions are symmetric
continue;
current.vertical_count_ = vertical_count;
&& me->get_bound (event_dir)->break_status_dir ())
{
current.horizontal_[event_dir]
- = (robust_relative_extent (me->get_bound (event_dir),
- commonx, X_AXIS)[RIGHT]
+ = (Axis_group_interface::generic_bound_extent (me->get_bound (event_dir),
+ commonx, X_AXIS)[RIGHT]
+ event_dir * break_overshoot[event_dir]);
}
else
current = Beam_segment ();
}
}
- while (flip (&event_dir) != LEFT);
}
}
+ SCM segments_scm = SCM_EOL;
+
+ for (vsize i = segments.size (); i--;)
+ {
+ segments_scm = scm_cons (scm_list_2 (scm_cons (ly_symbol2scm ("vertical-count"),
+ scm_from_int (segments[i].vertical_count_)),
+ scm_cons (ly_symbol2scm ("horizontal"),
+ ly_interval2scm (segments[i].horizontal_))),
+ segments_scm);
+ }
+
+ return segments_scm;
+}
+
+MAKE_SCHEME_CALLBACK (Beam, calc_x_positions, 1);
+SCM
+Beam::calc_x_positions (SCM smob)
+{
+ Spanner *me = unsmob<Spanner> (smob);
+ SCM segments = me->get_property ("beam-segments");
+ Interval x_positions;
+ x_positions.set_empty ();
+ for (SCM s = segments; scm_is_pair (s); s = scm_cdr (s))
+ x_positions.unite (robust_scm2interval (ly_assoc_get (ly_symbol2scm ("horizontal"),
+ scm_car (s),
+ SCM_EOL),
+ Interval (0.0, 0.0)));
+
+ // Case for beams without segments (i.e. uniting two skips with a beam)
+ // TODO: should issue a warning? warning likely issued downstream, but couldn't hurt...
+ if (x_positions.is_empty ())
+ {
+ extract_grob_set (me, "stems", stems);
+ Grob *common_x = common_refpoint_of_array (stems, me, X_AXIS);
+ for (LEFT_and_RIGHT (d))
+ x_positions[d] = me->relative_coordinate (common_x, X_AXIS);
+ }
+ return ly_interval2scm (x_positions);
+}
+
+vector<Beam_segment>
+Beam::get_beam_segments (Grob *me)
+{
+ SCM segments_scm = me->get_property ("beam-segments");
+ vector<Beam_segment> segments;
+ for (SCM s = segments_scm; scm_is_pair (s); s = scm_cdr (s))
+ {
+ segments.push_back (Beam_segment ());
+ segments.back ().vertical_count_ = robust_scm2int (ly_assoc_get (ly_symbol2scm ("vertical-count"), scm_car (s), SCM_EOL), 0);
+ segments.back ().horizontal_ = robust_scm2interval (ly_assoc_get (ly_symbol2scm ("horizontal"), scm_car (s), SCM_EOL), Interval (0.0, 0.0));
+ }
+
return segments;
}
SCM
Beam::print (SCM grob)
{
- Spanner *me = unsmob_spanner (grob);
- Grob *commonx = 0;
- vector<Beam_segment> segments = get_beam_segments (me, &commonx);
+ Spanner *me = unsmob<Spanner> (grob);
+ /*
+ TODO - mild code dup for all the commonx calls.
+ Some use just common_refpoint_of_array, some (in print and
+ calc_beam_segments) use this plus calls to get_bound.
+
+ Figure out if there is any particular reason for this and
+ consolidate in one Beam::get_common function.
+ */
+ extract_grob_set (me, "stems", stems);
+ Grob *commonx = common_refpoint_of_array (stems, me, X_AXIS);
+ for (LEFT_and_RIGHT (d))
+ commonx = me->get_bound (d)->common_refpoint (commonx, X_AXIS);
+
+ vector<Beam_segment> segments = get_beam_segments (me);
+
if (!segments.size ())
return SCM_EOL;
- Interval span;
- if (normal_stem_count (me))
- {
- span[LEFT] = first_normal_stem (me)->relative_coordinate (commonx, X_AXIS);
- span[RIGHT] = last_normal_stem (me)->relative_coordinate (commonx, X_AXIS);
- }
- else
- {
- extract_grob_set (me, "stems", stems);
- span[LEFT] = stems[0]->relative_coordinate (commonx, X_AXIS);
- span[RIGHT] = stems.back ()->relative_coordinate (commonx, X_AXIS);
- }
-
Real blot = me->layout ()->get_dimension (ly_symbol2scm ("blot-diameter"));
SCM posns = me->get_property ("quantized-positions");
+ Interval span = robust_scm2interval (me->get_property ("X-positions"), Interval (0, 0));
Interval pos;
if (!is_number_pair (posns))
{
Interval placements = robust_scm2interval (me->get_property ("normalized-endpoints"), Interval (0.0, 0.0));
Stencil the_beam;
-
- int extreme = (segments[0].vertical_count_ == 0
- ? segments[0].vertical_count_
- : segments.back ().vertical_count_);
+ vsize extreme = (segments[0].vertical_count_ == 0
+ ? segments[0].vertical_count_
+ : segments.back ().vertical_count_);
for (vsize i = 0; i < segments.size (); i++)
{
// we need two translations: the normal one and
// the one of the lowest segment
- int idx[] = {i, extreme};
+ size_t idx[] = {i, extreme};
Real translations[2];
for (int j = 0; j < 2; j++)
Direction stem_dir = stems.size () ? to_dir (stems[0]->get_property ("direction")) : UP;
- Stencil score = *unsmob_stencil (Text_interface::interpret_markup
+ Stencil score = *unsmob<Stencil> (Text_interface::interpret_markup
(me->layout ()->self_scm (), properties, annotation));
if (!score.is_empty ())
for (iterof (s, stems); s != stems.end (); s++)
{
Interval positions = Stem::head_positions (*s);
- Direction d = DOWN;
- do
+ for (DOWN_and_UP (d))
{
if (sign (positions[d]) == d)
extremes[d] = d * max (d * positions[d], d * extremes[d]);
}
- while (flip (&d) != DOWN);
}
Drul_array<int> total (0, 0);
if (!scm_is_number (scm))
return;
- Interval_set gaps;
-
- gaps.set_full ();
+ vector<Interval> forbidden_intervals;
extract_grob_set (me, "normal-stems", stems);
{
Grob *stem = stems[i];
- Interval head_extents = Stem::head_positions (stem);
- if (!head_extents.is_empty ())
+ Interval head_extents;
+ if (Stem::head_count (stem))
{
- head_extents[LEFT] += -1;
- head_extents[RIGHT] += 1;
+ head_extents = Stem::head_positions (stem);
+ head_extents.widen (1);
head_extents *= staff_space * 0.5;
/*
}
head_extents_array.push_back (head_extents);
- gaps.remove_interval (head_extents);
+ forbidden_intervals.push_back (head_extents);
}
Interval max_gap;
Real max_gap_len = 0.0;
- for (vsize i = gaps.allowed_regions_.size () - 1; i != VPOS; i--)
+ vector<Interval> allowed_regions
+ = Interval_set::interval_union (forbidden_intervals).complement ().intervals ();
+ for (vsize i = allowed_regions.size () - 1; i != VPOS; i--)
{
- Interval gap = gaps.allowed_regions_[i];
+ Interval gap = allowed_regions[i];
/*
the outer gaps are not knees.
SCM
Beam::calc_stem_shorten (SCM smob)
{
- Grob *me = unsmob_grob (smob);
+ Grob *me = unsmob<Grob> (smob);
/*
shortening looks silly for x staff beams
int beam_count = get_beam_count (me);
SCM shorten_list = me->get_property ("beamed-stem-shorten");
- if (shorten_list == SCM_EOL)
+ if (scm_is_null (shorten_list))
return scm_from_int (0);
Real staff_space = Staff_symbol_referencer::staff_space (me);
return scm_from_double (0.0);
}
-MAKE_SCHEME_CALLBACK (Beam, quanting, 2);
+MAKE_SCHEME_CALLBACK (Beam, quanting, 3);
SCM
-Beam::quanting (SCM smob, SCM posns)
+Beam::quanting (SCM smob, SCM ys_scm, SCM align_broken_intos)
{
- Grob *me = unsmob_grob (smob);
- Drul_array<Real> ys (0, 0);
- ys = robust_scm2drul (posns, ys);
- Beam_scoring_problem problem (me, ys);
+ Grob *me = unsmob<Grob> (smob);
+ Drul_array<Real> ys = robust_scm2drul (ys_scm, Drul_array<Real> (infinity_f, -infinity_f));
+ bool cbs = to_boolean (align_broken_intos);
+ Beam_scoring_problem problem (me, ys, cbs);
ys = problem.solve ();
+
return ly_interval2scm (ys);
}
for (SCM s = scm_car (beaming); scm_is_pair (s); s = scm_cdr (s))
{
- if (scm_c_memq (scm_car (s), scm_cdr (beaming)) != SCM_BOOL_F)
+ if (scm_is_true (ly_memv (scm_car (s), scm_cdr (beaming))))
l.add_point (scm_to_int (scm_car (s)));
}
SCM
Beam::set_stem_lengths (SCM smob)
{
- Grob *me = unsmob_grob (smob);
+ Grob *me = unsmob<Grob> (smob);
/* trigger callbacks. */
(void) me->get_property ("direction");
Grob *fvs = first_normal_stem (me);
Grob *lvs = last_normal_stem (me);
- Real xl = fvs ? fvs->relative_coordinate (common[X_AXIS], X_AXIS) : 0.0;
- Real xr = lvs ? lvs->relative_coordinate (common[X_AXIS], X_AXIS) : 0.0;
+ Interval x_span = robust_scm2interval (me->get_property ("X-positions"), Interval (0, 0));
Direction feather_dir = to_dir (me->get_property ("grow-direction"));
for (vsize i = 0; i < stems.size (); i++)
bool french = to_boolean (s->get_property ("french-beaming"));
Real stem_y = calc_stem_y (me, s, common,
- xl, xr, feather_dir,
+ x_span[LEFT], x_span[RIGHT], feather_dir,
pos, french && s != lvs && s != fvs);
/*
{
extract_grob_set (me, "stems", stems);
- Direction d = LEFT;
for (vsize i = 0; i < stems.size (); i++)
{
/*
Don't overwrite user settings.
*/
- do
+ for (LEFT_and_RIGHT (d))
{
Grob *stem = stems[i];
SCM beaming_prop = stem->get_property ("beaming");
- if (beaming_prop == SCM_EOL
- || index_get_cell (beaming_prop, d) == SCM_EOL)
+ if (scm_is_null (beaming_prop)
+ || scm_is_null (index_get_cell (beaming_prop, d)))
{
int count = beaming->beamlet_count (i, d);
if (i > 0
Stem::set_beaming (stem, count, d);
}
}
- while (flip (&d) != LEFT);
}
}
SCM
Beam::rest_collision_callback (SCM smob, SCM prev_offset)
{
- Grob *rest = unsmob_grob (smob);
+ if (!scm_is_number (prev_offset))
+ prev_offset = SCM_INUM0;
+
+ Grob *rest = unsmob<Grob> (smob);
if (scm_is_number (rest->get_property ("staff-position")))
- return scm_from_int (0);
+ return prev_offset;
- Real offset = robust_scm2double (prev_offset, 0.0);
+ Grob *stem = unsmob<Grob> (rest->get_object ("stem"));
- Grob *st = unsmob_grob (rest->get_object ("stem"));
- Grob *stem = st;
if (!stem)
- return scm_from_double (0.0);
- Grob *beam = unsmob_grob (stem->get_object ("beam"));
+ return prev_offset;
+
+ Grob *beam = unsmob<Grob> (stem->get_object ("beam"));
if (!beam
- || !Beam::has_interface (beam)
+ || !has_interface<Beam> (beam)
|| !Beam::normal_stem_count (beam))
- return scm_from_double (0.0);
+ return prev_offset;
+
+ Grob *common_y = rest->common_refpoint (beam, Y_AXIS);
Drul_array<Real> pos (robust_scm2drul (beam->get_property ("positions"),
Drul_array<Real> (0, 0)));
+ for (LEFT_and_RIGHT (dir))
+ pos[dir] += beam->relative_coordinate (common_y, Y_AXIS);
+
Real staff_space = Staff_symbol_referencer::staff_space (rest);
scale_drul (&pos, staff_space);
Real dy = pos[RIGHT] - pos[LEFT];
- Drul_array<Grob *> visible_stems (first_normal_stem (beam),
- last_normal_stem (beam));
extract_grob_set (beam, "stems", stems);
-
Grob *common = common_refpoint_of_array (stems, beam, X_AXIS);
- Real x0 = visible_stems[LEFT]->relative_coordinate (common, X_AXIS);
- Real dx = visible_stems[RIGHT]->relative_coordinate (common, X_AXIS) - x0;
+ Interval x_span = robust_scm2interval (beam->get_property ("X-positions"),
+ Interval (0.0, 0.0));
+ Real x0 = x_span[LEFT];
+ Real dx = x_span.length ();
Real slope = dy && dx ? dy / dx : 0;
Direction d = get_grob_direction (stem);
+ (beam_count - 1) * beam_translation;
Real beam_y = stem_y - d * height_of_my_beams;
- Grob *common_y = rest->common_refpoint (beam, Y_AXIS);
-
+ Real offset = robust_scm2double (prev_offset, 0.0);
Interval rest_extent = rest->extent (rest, Y_AXIS);
- rest_extent.translate (offset + rest->get_parent (Y_AXIS)->relative_coordinate (common_y, Y_AXIS));
+ rest_extent.translate (offset + rest->parent_relative (common_y, Y_AXIS));
Real rest_dim = rest_extent[d];
Real minimum_distance
Real shift = d * min (d * (beam_y - d * minimum_distance - rest_dim), 0.0);
shift /= staff_space;
- Real rad = Staff_symbol_referencer::line_count (rest) * staff_space / 2;
/* Always move discretely by half spaces */
shift = ceil (fabs (shift * 2.0)) / 2.0 * sign (shift);
+ Interval staff_span = Staff_symbol_referencer::staff_span (rest);
+ staff_span *= staff_space / 2;
+
/* Inside staff, move by whole spaces*/
- if ((rest_extent[d] + staff_space * shift) * d
- < rad
- || (rest_extent[-d] + staff_space * shift) * -d
- < rad)
+ if (staff_span.contains (rest_extent[d] + staff_space * shift)
+ || staff_span.contains (rest_extent[-d] + staff_space * shift))
shift = ceil (fabs (shift)) * sign (shift);
return scm_from_double (offset + staff_space * shift);
}
+/*
+ Estimate the position of a rest under a beam,
+ using the average position of its neighboring heads.
+*/
MAKE_SCHEME_CALLBACK_WITH_OPTARGS (Beam, pure_rest_collision_callback, 4, 1, "");
SCM
Beam::pure_rest_collision_callback (SCM smob,
- SCM, /* prev_offset */
SCM, /* start */
- SCM /* end */)
+ SCM, /* end */
+ SCM prev_offset)
{
- Real amount = 0.0;
+ if (!scm_is_number (prev_offset))
+ prev_offset = SCM_INUM0;
- Grob *me = unsmob_grob (smob);
- Grob *stem = unsmob_grob (me->get_object ("stem"));
+ Grob *me = unsmob<Grob> (smob);
+ Grob *stem = unsmob<Grob> (me->get_object ("stem"));
if (!stem)
- return scm_from_double (amount);
- Grob *beam = unsmob_grob (stem->get_object ("beam"));
+ return prev_offset;
+ Grob *beam = unsmob<Grob> (stem->get_object ("beam"));
if (!beam
- || !Beam::normal_stem_count (beam))
- return scm_from_double (amount);
+ || !Beam::normal_stem_count (beam)
+ || !is_direction (beam->get_property_data ("direction")))
+ return prev_offset;
Real ss = Staff_symbol_referencer::staff_space (me);
- /*
- This gives the extrema of rest positions.
- In general, beams are never typeset more than one staff space away
- from the staff in either direction.
- */
- Grob *staff = Staff_symbol_referencer::get_staff_symbol (me);
- Interval rest_max_pos = staff ? Staff_symbol::line_span (staff) : Interval (0.0, 0.0);
- rest_max_pos.widen (1);
- rest_max_pos *= ss / 2;
-
extract_grob_set (beam, "stems", stems);
vector<Grob *> my_stems;
Grob *left;
Grob *right;
- if (idx == (vsize)-1 || my_stems.size () == 1)
- return scm_from_double (amount);
+ if (idx == (vsize) - 1 || my_stems.size () == 1)
+ return prev_offset;
else if (idx == 0)
left = right = my_stems[1];
else if (idx == my_stems.size () - 1)
left = my_stems[idx - 1];
right = my_stems[idx + 1];
}
+
+ /* Estimate the closest beam to be four positions away from the heads, */
Direction beamdir = get_grob_direction (beam);
- /*
- Take the position between the two bounding head_positions,
- then bound it by the minimum and maximum positions outside the staff.
- 4.0 = 2.0 to get out of staff space * 2.0 for the average
- */
- amount = min (max ((Stem::head_positions (left)[beamdir] + Stem::head_positions (right)[beamdir]) / 4.0, rest_max_pos[DOWN]), rest_max_pos[UP]);
+ Real beam_pos = (Stem::head_positions (left)[beamdir]
+ + Stem::head_positions (right)[beamdir]) / 2.0
+ + 4.0 * beamdir; // four staff-positions
+ /* and that the closest beam never crosses staff center by more than two positions */
+ beam_pos = max (-2.0, beam_pos * beamdir) * beamdir;
- return scm_from_double (amount);
+ Real minimum_distance
+ = ss * (robust_scm2double (stem->get_property ("stemlet-length"), 0.0)
+ + robust_scm2double (me->get_property ("minimum-distance"), 0.0));
+ Real offset = beam_pos * ss / 2.0
+ - minimum_distance * beamdir
+ - me->extent (me, Y_AXIS)[beamdir];
+ Real previous = robust_scm2double (prev_offset, 0.0);
+
+ /* Always move by a whole number of staff spaces, always away from the beam */
+ offset = floor (min (0.0, (offset - previous) / ss * beamdir))
+ * ss * beamdir + previous;
+
+ return scm_from_double (offset);
}
-
bool
Beam::is_knee (Grob *me)
{
SCM
Beam::calc_cross_staff (SCM smob)
{
- return scm_from_bool (is_cross_staff (unsmob_grob (smob)));
+ return scm_from_bool (is_cross_staff (unsmob<Grob> (smob)));
}
int
" measured in staffspace. The @code{direction} property is"
" not user-serviceable. Use the @code{direction} property"
" of @code{Stem} instead.\n"
- "\n"
"The following properties may be set in the @code{details}"
" list.\n"
"\n"
"auto-knee-gap "
"beamed-stem-shorten "
"beaming "
+ "beam-segments "
"beam-thickness "
"break-overshoot "
"clip-edges "
"positions "
"quantized-positions "
"shorten "
+ "skip-quanting "
"stems "
+ "X-positions "
);