#include "misc.hh"
#include "least-squares.hh"
#include "stem.hh"
-#include "paper-def.hh"
+#include "output-def.hh"
#include "lookup.hh"
#include "group-interface.hh"
#include "staff-symbol-referencer.hh"
#include "spanner.hh"
#include "warn.hh"
-bool debug_beam_quanting_flag;
-
#if DEBUG_QUANTING
#include "text-item.hh" // debug output.
{
SCM func = me->get_property ("space-function");
- if (gh_procedure_p (func))
+ if (ly_c_procedure_p (func))
{
- SCM s = gh_call2 (func, me->self_scm (), scm_int2num (get_beam_count (me)));
- return gh_scm2double (s);
+ SCM s = scm_call_2 (func, me->self_scm (), scm_int2num (get_beam_count (me)));
+ return scm_to_double (s);
}
else
{
Beam::get_beam_count (Grob *me)
{
int m = 0;
- for (SCM s = me->get_property ("stems"); gh_pair_p (s); s = ly_cdr (s))
+ for (SCM s = me->get_property ("stems"); ly_c_pair_p (s); s = ly_cdr (s))
{
Grob *stem = unsmob_grob (ly_car (s));
m = m >? (Stem::beam_multiplicity (stem).length () + 1);
Real line = Staff_symbol_referencer::line_thickness (me);
Real thickness = get_thickness (me);
- Real beam_translation = gh_scm2int (beam_count) < 4
+ Real beam_translation = scm_to_int (beam_count) < 4
? (2*staff_space + line - thickness) / 2.0
: (3*staff_space + line - thickness) / 3.0;
- return gh_double2scm (beam_translation);
+ return scm_make_real (beam_translation);
}
SCM stems = me->get_property ("stems");
if (scm_ilength (stems) == 1)
{
- me->warning (_ ("Beam has less than two stems. Removing beam."));
+ me->warning (_ ("removing beam with less than two stems"));
- unsmob_grob (gh_car (stems))->set_property ("beam", SCM_EOL);
+ unsmob_grob (ly_car (stems))->set_property ("beam", SCM_EOL);
me->suicide ();
return SCM_UNSPECIFIED;
Direction left_dir,
Direction right_dir)
{
- Slice lslice = int_list_to_slice (gh_cdr (left_beaming));
+ Slice lslice = int_list_to_slice (ly_cdr (left_beaming));
int best_count = 0;
int best_start = 0;
(i - lslice[left_dir])* left_dir <= 0 ; i+= left_dir)
{
int count =0;
- for ( SCM s = gh_car (right_beaming); gh_pair_p (s); s = gh_cdr (s))
+ for ( SCM s = ly_car (right_beaming); ly_c_pair_p (s); s = ly_cdr (s))
{
- int k = - right_dir * gh_scm2int (gh_car (s)) + i;
- if (scm_memq (scm_int2num (k), left_beaming) != SCM_BOOL_F)
+ int k = - right_dir * scm_to_int (ly_car (s)) + i;
+ if (scm_c_memq (scm_int2num (k), left_beaming) != SCM_BOOL_F)
count ++;
}
SCM this_beaming = this_stem->get_property ("beaming");
Direction this_dir = get_grob_direction (this_stem);
- if (gh_pair_p (last_beaming) && gh_pair_p (this_beaming))
+ if (ly_c_pair_p (last_beaming) && ly_c_pair_p (this_beaming))
{
int start_point = position_with_maximal_common_beams
(last_beaming, this_beaming,
new_slice.set_empty ();
SCM s = index_get_cell (this_beaming, d);
- for (; gh_pair_p (s); s = gh_cdr (s))
+ for (; ly_c_pair_p (s); s = ly_cdr (s))
{
int new_beam_pos =
- start_point - this_dir * gh_scm2int (gh_car (s));
+ start_point - this_dir * scm_to_int (ly_car (s));
new_slice.add_point (new_beam_pos);
- gh_set_car_x (s, scm_int2num (new_beam_pos));
+ scm_set_car_x (s, scm_int2num (new_beam_pos));
}
}
else
{
- gh_set_car_x ( this_beaming, SCM_EOL);
- SCM s = gh_cdr (this_beaming);
- for (; gh_pair_p (s); s = gh_cdr (s))
+ scm_set_car_x ( this_beaming, SCM_EOL);
+ SCM s = ly_cdr (this_beaming);
+ for (; ly_c_pair_p (s); s = ly_cdr (s))
{
- int np = - this_dir * gh_scm2int (gh_car (s));
- gh_set_car_x (s, scm_int2num (np));
+ int np = - this_dir * scm_to_int (ly_car (s));
+ scm_set_car_x (s, scm_int2num (np));
last_int.add_point (np);
}
}
if (i == stems.size () -1)
{
- gh_set_cdr_x (this_beaming, SCM_EOL);
+ scm_set_cdr_x (this_beaming, SCM_EOL);
}
- if (scm_ilength (gh_cdr (this_beaming)) > 0)
+ if (scm_ilength (ly_cdr (this_beaming)) > 0)
{
last_beaming = this_beaming;
last_dir = this_dir;
else
pos= ly_scm2realdrul (posns);
- scale_drul ( &pos, Staff_symbol_referencer::staff_space (me));
+ scale_drul (&pos, Staff_symbol_referencer::staff_space (me));
Real dy = pos[RIGHT] - pos[LEFT];
- Real dydx = (dy && dx) ? dy/dx : 0;
+ Real slope = (dy && dx) ? dy/dx : 0;
Real thick = get_thickness (me);
Real bdy = get_beam_translation (me);
Real last_xposn = -1;
Real last_stem_width = -1 ;
- Real gap_length =robust_scm2double ( me->get_property ("gap"), 0.0);
+ Real gap_length = robust_scm2double (me->get_property ("gap"), 0.0);
Stencil the_beam;
- Real lt = me->get_paper ()->get_realvar (ly_symbol2scm ("linethickness"));
+ Real lt = me->get_paper ()->get_dimension (ly_symbol2scm ("linethickness"));
for (int i = 0; i<= stems.size (); i++)
{
right from the left stem, and rfliebertjes pointing left from
right stem.
*/
- SCM left = (i>0) ? gh_cdr (last_beaming) : SCM_EOL;
- SCM right = st ? gh_car (this_beaming) : SCM_EOL;
+ SCM left = (i > 0) ? ly_cdr (last_beaming) : SCM_EOL;
+ SCM right = st ? ly_car (this_beaming) : SCM_EOL;
Array<int> full_beams;
Array<int> lfliebertjes;
Array<int> rfliebertjes;
for (SCM s = left;
- gh_pair_p (s); s =gh_cdr (s))
+ ly_c_pair_p (s); s =ly_cdr (s))
{
- int b = gh_scm2int (gh_car (s));
- if (scm_memq (gh_car (s), right) != SCM_BOOL_F)
+ int b = scm_to_int (ly_car (s));
+ if (scm_c_memq (ly_car (s), right) != SCM_BOOL_F)
{
full_beams.push (b);
}
}
}
for (SCM s = right;
- gh_pair_p (s); s =gh_cdr (s))
+ ly_c_pair_p (s); s =ly_cdr (s))
{
- int b = gh_scm2int (gh_car (s));
- if (scm_memq (gh_car (s), left) == SCM_BOOL_F)
+ int b = scm_to_int (ly_car (s));
+ if (scm_c_memq (ly_car (s), left) == SCM_BOOL_F)
{
rfliebertjes.push (b);
}
w += stem_width/ 2 ;
- Real blot = me->get_paper ()->get_realvar (ly_symbol2scm ("blotdiameter"));
- Stencil whole = Lookup::beam (dydx, w, thick, blot);
+ Real blot = me->get_paper ()->get_dimension (ly_symbol2scm ("blotdiameter"));
+ Stencil whole = Lookup::beam (slope, w, thick, blot);
Stencil gapped;
int gap_count = 0;
- if (gh_number_p (me->get_property ("gap-count")))
+ if (scm_is_number (me->get_property ("gap-count")))
{
- gap_count = gh_scm2int (me->get_property ("gap-count"));
- gapped = Lookup::beam (dydx, w - 2 * gap_length, thick, blot);
+ gap_count = scm_to_int (me->get_property ("gap-count"));
+ gapped = Lookup::beam (slope, w - 2 * gap_length, thick, blot);
full_beams.sort (default_compare);
if (stem_dir == UP)
b.translate_axis (gap_length, X_AXIS);
}
b.translate_axis (last_xposn - x0 + stem_offset, X_AXIS);
- b.translate_axis (dydx * (last_xposn - x0) + bdy * full_beams[j], Y_AXIS);
+ b.translate_axis (slope * (last_xposn - x0) + bdy * full_beams[j], Y_AXIS);
the_beam.add_stencil (b);
}
int t = Stem::duration_log (st);
SCM proc = me->get_property ("flag-width-function");
- SCM result = gh_call1 (proc, scm_int2num (t));
- nw_f = gh_scm2double (result);
+ SCM result = scm_call_1 (proc, scm_int2num (t));
+ nw_f = scm_to_double (result);
}
else
nw_f = break_overshoot / 2;
lw = me->get_bound (RIGHT)->relative_coordinate (xcommon, X_AXIS)
- last_xposn;
- Stencil rhalf = Lookup::beam (dydx, rw, thick, blot);
- Stencil lhalf = Lookup::beam (dydx, lw, thick, blot);
+ Stencil rhalf = Lookup::beam (slope, rw, thick, blot);
+ Stencil lhalf = Lookup::beam (slope, lw, thick, blot);
for (int j = lfliebertjes.size (); j--;)
{
Stencil b (lhalf);
b.translate_axis (last_xposn - x0, X_AXIS);
- b.translate_axis (dydx * (last_xposn-x0) + bdy * lfliebertjes[j], Y_AXIS);
+ b.translate_axis (slope * (last_xposn-x0) + bdy * lfliebertjes[j], Y_AXIS);
the_beam.add_stencil (b);
}
for (int j = rfliebertjes.size (); j--;)
{
Stencil b (rhalf);
b.translate_axis (xposn - x0 - rw , X_AXIS);
- b.translate_axis (dydx * (xposn-x0 -rw) + bdy * rfliebertjes[j], Y_AXIS);
+ b.translate_axis (slope * (xposn-x0 -rw) + bdy * rfliebertjes[j], Y_AXIS);
the_beam.add_stencil (b);
}
}
#if (DEBUG_QUANTING)
SCM quant_score = me->get_property ("quant-score");
- if (debug_beam_quanting_flag
- && gh_string_p (quant_score))
+ if (to_boolean (me->get_paper ()->lookup_variable (ly_symbol2scm ("debug-beam-quanting")))
+ && scm_is_string (quant_score))
{
/*
String str;
SCM properties = Font_interface::text_font_alist_chain (me);
+ Direction stem_dir = stems.size() ? to_dir (stems[0]->get_property ("direction")) : UP;
+
Stencil tm = *unsmob_stencil (Text_item::interpret_markup
(me->get_paper ()->self_scm (), properties, quant_score));
- the_beam.add_at_edge (Y_AXIS, UP, tm, 5.0, 0);
+ the_beam.add_at_edge (Y_AXIS, stem_dir, tm, 1.0, 0);
}
#endif
-
-
return the_beam.smobbed_copy ();
}
Link_array<Grob> stems=
Pointer_group_interface__extract_grobs (me, (Grob*)0, "stems");
- for (int i=0; i <stems.size (); i++)
+ for (int i=0; i < stems.size (); i++)
do {
Grob *s = stems[i];
Direction sd = get_grob_direction (s);
} while (flip (&d) != DOWN);
SCM func = me->get_property ("dir-function");
- SCM s = gh_call2 (func,
- gh_cons (scm_int2num (count[UP]),
+ SCM s = scm_call_2 (func,
+ scm_cons (scm_int2num (count[UP]),
scm_int2num (count[DOWN])),
- gh_cons (scm_int2num (total[UP]),
+ scm_cons (scm_int2num (total[UP]),
scm_int2num (total[DOWN])));
- if (gh_number_p (s) && gh_scm2int (s))
+ if (scm_is_number (s) && scm_to_int (s))
return to_dir (s);
/* If dir is not determined: get default */
Beam::consider_auto_knees (Grob* me)
{
SCM scm = me->get_property ("auto-knee-gap");
- if (!gh_number_p (scm))
+ if (!scm_is_number (scm))
return ;
- Real threshold = gh_scm2double (scm);
+ Real threshold = scm_to_double (scm);
Int_set gaps;
SCM shorten_elt =
robust_list_ref (beam_count -1, shorten_list);
- Real shorten_f = gh_scm2double (shorten_elt) * staff_space;
+ Real shorten_f = scm_to_double (shorten_elt) * staff_space;
/* your similar cute comment here */
shorten_f *= forced_fraction;
if (shorten_f)
- me->set_property ("shorten", gh_double2scm (shorten_f));
+ me->set_property ("shorten", scm_make_real (shorten_f));
}
/* Call list of y-dy-callbacks, that handle setting of
{
// one wonders if such genericity is necessary --hwn.
SCM callbacks = me->get_property ("position-callbacks");
- for (SCM i = callbacks; gh_pair_p (i); i = ly_cdr (i))
- gh_call1 (ly_car (i), me->self_scm ());
+ for (SCM i = callbacks; ly_c_pair_p (i); i = ly_cdr (i))
+ scm_call_1 (ly_car (i), me->self_scm ());
}
set_stem_lengths (me);
}
+void
+set_minimum_dy (Grob *me, Real * dy)
+{
+ if (*dy)
+ {
+ /*
+ If dy is smaller than the smallest quant, we
+ get absurd direction-sign penalties.
+ */
+
+ Real ss = Staff_symbol_referencer::staff_space (me);
+ Real thickness = Beam::get_thickness (me) / ss ;
+ Real slt = Staff_symbol_referencer::line_thickness (me) / ss;
+ Real sit = (thickness - slt) / 2;
+ Real inter = 0.5;
+ Real hang = 1.0 - (thickness - slt) / 2;
+
+ *dy = sign (*dy) * (fabs (*dy)
+ >?
+ (sit <? inter <? hang));
+ }
+}
+
/*
Compute a first approximation to the beam slope.
*/
Real y =0;
- Real dydx = 0;
+ Real slope = 0;
Real dy = 0;
if (!ideal.delta ())
/*
For broken beams this doesn't work well. In this case, the
- slope esp. of the first part of a broken beam should predict
- where the second part goes.
- */
+ slope esp. of the first part of a broken beam should predict
+ where the second part goes.
+ */
me->set_property ("least-squares-dy",
- gh_double2scm (pos[RIGHT] - pos[LEFT]));
+ scm_make_real (pos[RIGHT] - pos[LEFT]));
}
else
{
- my_y));
}
- minimise_least_squares (&dydx, &y, ideals);
+ minimise_least_squares (&slope, &y, ideals);
- dy = dydx * dx;
- me->set_property ("least-squares-dy", gh_double2scm (dy));
+ dy = slope * dx;
+
+ set_minimum_dy (me,&dy);
+ me->set_property ("least-squares-dy", scm_make_real (dy));
pos = Interval (y, (y+dy));
}
We can't combine with previous function, since check concave and
slope damping comes first.
-TODO: we should use the concaveness to control the amount of damping
-applied.
+ TODO: we should use the concaveness to control the amount of damping
+ applied.
- */
+*/
MAKE_SCHEME_CALLBACK (Beam, shift_region_to_valid, 1);
SCM
Beam::shift_region_to_valid (SCM grob)
Real dy = pos[RIGHT] - pos[LEFT];
Real y = pos[LEFT];
- Real dydx =dy/dx;
+ Real slope =dy/dx;
/*
Real left_y =
Stem::get_stem_info (s).shortest_y_
- - dydx * x_posns [i];
+ - slope * x_posns [i];
/*
left_y is now relative to the stem S. We want relative to
}
if (feasible_left_point.is_empty ())
- {
- warning (_ ("Not sure that we can find a nice beam slope (no viable initial configuration found)."));
- }
+ warning (_ ("no viable initial configuration found: may not find good beam slope"));
else if (!feasible_left_point.contains (y))
{
if (isinf (feasible_left_point[DOWN]))
return SCM_UNSPECIFIED;
}
-MAKE_SCHEME_CALLBACK (Beam, check_concave, 1);
-SCM
-Beam::check_concave (SCM smob)
-{
- Grob *me = unsmob_grob (smob);
-
- Link_array<Grob> stems =
- Pointer_group_interface__extract_grobs (me, (Grob*) 0, "stems");
-
- Direction beam_dir = CENTER;
- for (int i = 0; i < stems.size ();)
- {
- if (Stem::is_invisible (stems[i]))
- stems.del (i);
- else
- {
- if (Direction sd = Stem::get_direction (stems[i]))
- {
- /*
- Don't do knee beams.
- */
- if (beam_dir && sd && sd != beam_dir)
- return SCM_UNSPECIFIED;
-
- beam_dir = sd;
- }
- i++;
- }
- }
-
- if (stems.size () < 3)
- return SCM_UNSPECIFIED;
-
-
- /* Concaveness #1: If distance of an inner notehead to line between
- two outer noteheads is bigger than CONCAVENESS-GAP (2.0ss),
- beam is concave (Heinz Stolba).
-
- In the case of knees, the line connecting outer heads is often
- not related to the beam slope (it may even go in the other
- direction). Skip the check when the outer stems point in
- different directions. --hwn
-
- */
- bool is_concave1 = false;
- SCM gap = me->get_property ("concaveness-gap");
- if (gh_number_p (gap))
- {
- Real r1 = gh_scm2double (gap);
- Real dy = Stem::chord_start_y (stems.top ())
- - Stem::chord_start_y (stems[0]);
-
-
- Real slope = dy / (stems.size () - 1);
-
- Real y0 = Stem::chord_start_y (stems[0]);
- for (int i = 1; i < stems.size () - 1; i++)
- {
- Real c =
- beam_dir *((Stem::chord_start_y (stems[i]) - y0) - i * slope);
- if (c - r1 > 0)
- {
- is_concave1 = true;
- break;
- }
- }
- }
-
-
- /* Concaveness #2: Sum distances of inner noteheads that fall
- outside the interval of the two outer noteheads.
-
- We only do this for beams where first and last stem have the same
- direction. --hwn.
-
-
- Note that "convex" stems compensate for "concave" stems.
- (is that intentional?) --hwn.
- */
-
- Real concaveness2 = 0;
- SCM thresh = me->get_property ("concaveness-threshold");
- Real r2 = infinity_f;
- if (!is_concave1 && gh_number_p (thresh))
- {
- r2 = gh_scm2double (thresh);
-
- Interval iv;
- iv.add_point (Stem::chord_start_y (stems[0]));
- iv.add_point (Stem::chord_start_y (stems.top ()));
-
- for (int i = 1; i < stems.size () - 1; i++)
- {
- Real f = Stem::chord_start_y (stems[i]);
- concaveness2 += ( (f - iv[MAX] ) >? 0) +
- ( (f - iv[MIN] ) <? 0);
- }
-
- concaveness2 *= beam_dir / (stems.size () - 2);
- }
-
- /* TODO: some sort of damping iso -> plain horizontal */
- if (is_concave1 || concaveness2 > r2)
- {
- Drul_array<Real> pos = ly_scm2interval (me->get_property ("positions"));
- Real r = linear_combination (pos, 0);
-
- r /= Staff_symbol_referencer::staff_space (me);
- me->set_property ("positions", ly_interval2scm (Drul_array<Real> (r, r)));
- me->set_property ("least-squares-dy", gh_double2scm (0));
- }
-
- return SCM_UNSPECIFIED;
-}
-
/* This neat trick is by Werner Lemberg,
damped = tanh (slope)
corresponds with some tables in [Wanske] CHECKME */
return SCM_UNSPECIFIED;
SCM s = me->get_property ("damping");
- int damping = gh_scm2int (s);
+ Real damping = scm_to_double (s);
if (damping)
{
- Drul_array<Real> pos = ly_scm2interval (me->get_property ("positions"));
+ Drul_array<Real> pos = ly_scm2interval (me->get_property ("positions"));
scale_drul (&pos, Staff_symbol_referencer::staff_space (me));
Real dy = pos[RIGHT] - pos[LEFT];
Real dx = last_visible_stem (me)->relative_coordinate (commonx, X_AXIS)
- first_visible_stem (me)->relative_coordinate (commonx, X_AXIS);
- Real dydx = dy && dx ? dy/dx : 0;
- dydx = 0.6 * tanh (dydx) / damping;
- Real damped_dy = dydx * dx;
+ Real slope = dy && dx ? dy/dx : 0;
+
+ Real concaveness = robust_scm2double (me->get_property ("concaveness"), 0.0);
+
+ slope = 0.6 * tanh (slope) / (damping + concaveness);
+
+ Real damped_dy = slope * dx;
+
+ set_minimum_dy (me, &damped_dy);
+
pos[LEFT] += (dy - damped_dy) / 2;
pos[RIGHT] -= (dy - damped_dy) / 2;
{
Slice l;
- for ( SCM s = gh_car (beaming); gh_pair_p (s) ; s = gh_cdr (s))
+ for ( SCM s = ly_car (beaming); ly_c_pair_p (s) ; s = ly_cdr (s))
{
- if (scm_memq (gh_car (s), gh_cdr (beaming)) != SCM_BOOL_F)
+ if (scm_c_memq (ly_car (s), ly_cdr (beaming)) != SCM_BOOL_F)
- l.add_point (gh_scm2int (gh_car (s)));
+ l.add_point (scm_to_int (ly_car (s)));
}
return l;
bool gap = false;
Real thick =0.0;
- if (gh_number_p (me->get_property ("gap-count"))
- &&gh_scm2int (me->get_property ("gap-count")))
+ if (scm_is_number (me->get_property ("gap-count"))
+ &&scm_to_int (me->get_property ("gap-count")))
{
gap = true;
thick = get_thickness (me);
Beam::rest_collision_callback (SCM element_smob, SCM axis)
{
Grob *rest = unsmob_grob (element_smob);
- Axis a = (Axis) gh_scm2int (axis);
+ Axis a = (Axis) scm_to_int (axis);
- if (gh_number_p (rest->get_property ("staff-position")))
- return gh_int2scm (0);
+ if (scm_is_number (rest->get_property ("staff-position")))
+ return scm_int2num (0);
assert (a == Y_AXIS);
Grob *st = unsmob_grob (rest->get_property ("stem"));
Grob *stem = st;
if (!stem)
- return gh_double2scm (0.0);
+ return scm_make_real (0.0);
Grob *beam = unsmob_grob (stem->get_property ("beam"));
if (!beam
|| !Beam::has_interface (beam)
|| !Beam::visible_stem_count (beam))
- return gh_double2scm (0.0);
+ return scm_make_real (0.0);
Drul_array<Real> pos (0, 0);
SCM s = beam->get_property ("positions");
- if (gh_pair_p (s) && gh_number_p (ly_car (s)))
+ if (ly_c_pair_p (s) && scm_is_number (ly_car (s)))
pos = ly_scm2interval (s);
Real staff_space = Staff_symbol_referencer::staff_space (rest);
// ugh -> use commonx
Real x0 = first_visible_stem (beam)->relative_coordinate (0, X_AXIS);
Real dx = last_visible_stem (beam)->relative_coordinate (0, X_AXIS) - x0;
- Real dydx = dy && dx ? dy/dx : 0;
+ Real slope = dy && dx ? dy/dx : 0;
Direction d = Stem::get_direction (stem);
- Real stem_y = pos[LEFT] + (stem->relative_coordinate (0, X_AXIS) - x0) * dydx;
+ Real stem_y = pos[LEFT] + (stem->relative_coordinate (0, X_AXIS) - x0) * slope;
Real beam_translation = get_beam_translation (beam);
Real beam_thickness = Beam::get_thickness (beam);
< rad)
shift = ceil (fabs (shift)) *sign (shift);
- return gh_double2scm (staff_space * shift);
+ return scm_make_real (staff_space * shift);
}
bool
Beam::is_knee (Grob* me)
{
SCM k = me->get_property ("knee");
- if (gh_boolean_p (k))
- return gh_scm2bool (k);
+ if (scm_is_bool (k))
+ return ly_scm2bool (k);
bool knee = false;
int d = 0;
- for (SCM s = me->get_property ("stems"); gh_pair_p (s); s = ly_cdr (s))
+ for (SCM s = me->get_property ("stems"); ly_c_pair_p (s); s = ly_cdr (s))
{
Direction dir = get_grob_direction (unsmob_grob (ly_car (s)));
if (d && d != dir)
d = dir;
}
- me->set_property ("knee", gh_bool2scm (knee));
+ me->set_property ("knee", ly_bool2scm (knee));
return knee;
}
"The @code{thickness} property is the weight of beams, and is measured "
"in staffspace"
,
- "knee positioning-done position-callbacks concaveness-gap "
- "concaveness-threshold dir-function quant-score auto-knee-gap gap "
+ "knee positioning-done position-callbacks "
+ "concaveness dir-function quant-score auto-knee-gap gap "
"gap-count chord-tremolo beamed-stem-shorten shorten least-squares-dy "
- "damping flag-width-function neutral-direction positions space-function "
+ "damping inspect-quants flag-width-function neutral-direction positions space-function "
"thickness");