/*
beam.cc -- implement Beam
-
+
source file of the GNU LilyPond music typesetter
-
- (c) 1997--2002 Han-Wen Nienhuys <hanwen@cs.uu.nl>
- Jan Nieuwenhuizen <janneke@gnu.org>
-
+
+ (c) 1997--2002 Han-Wen Nienhuys <hanwen@cs.uu.nl>
+ Jan Nieuwenhuizen <janneke@gnu.org>
+
*/
/*
static Real
shrink_extra_weight (Real x)
{
- return fabs(x) * ((x < 0) ? 1.5 : 1.0);
+ return fabs (x) * ((x < 0) ? 1.5 : 1.0);
}
-
void
Beam::add_stem (Grob *me, Grob *s)
{
add_bound_item (dynamic_cast<Spanner*> (me), dynamic_cast<Item*> (s));
}
+Real
+Beam::get_interbeam (Grob *me)
+{
+ Real slt = me->paper_l ()->get_var ("stafflinethickness");
+ Real ss = Staff_symbol_referencer::staff_space (me);
+ Real thickness = gh_scm2double (me->get_grob_property ("thickness"))
+ * ss;
+
+ int multiplicity = get_multiplicity (me);
+ Real interbeam = multiplicity < 4
+ ? (2*ss + slt - thickness) / 2.0
+ : (3*ss + slt - thickness) / 3.0;
+
+ return interbeam;
+}
+
int
Beam::get_multiplicity (Grob *me)
{
grob-properties y, dy.
User may set grob-properties: y-position-hs and height-hs
- (to be fixed) that override the calculated y and dy.
+ (to be fixed) that override the calculated y and dy.
Because y and dy cannot be calculated and quanted separately, we
always calculate both, then check for user override. */
Real demerits;
};
-
-MAKE_SCHEME_CALLBACK (Beam, new_quanting, 1);
+/*
+ TODO:
+ - Make all demerits customisable
+ - One sensible check per demerit
+ - Add demerits for quants per se, as to forbid a specific quant
+ entirely
+ */
+MAKE_SCHEME_CALLBACK (Beam, quanting, 1);
SCM
-Beam::new_quanting (SCM smob)
+Beam::quanting (SCM smob)
{
Grob *me = unsmob_grob (smob);
SCM s = me->get_grob_property ("positions");
- Real yl = gh_scm2double (gh_car(s));
- Real yr = gh_scm2double (gh_cdr(s));
+ Real yl = gh_scm2double (gh_car (s));
+ Real yr = gh_scm2double (gh_cdr (s));
Real ss = Staff_symbol_referencer::staff_space (me);
Real thickness = gh_scm2double (me->get_grob_property ("thickness")) / ss;
- Real slt = me->paper_l()->get_var ("stafflinethickness") / ss;
+ Real slt = me->paper_l ()->get_var ("stafflinethickness") / ss;
Real straddle = 0.0;
Real sit = (thickness - slt) / 2;
Real hang = 1.0 - (thickness - slt) / 2;
Real quants [] = {straddle, sit, inter, hang };
- int num_quants = int(sizeof(quants)/sizeof (Real));
+ int num_quants = int (sizeof (quants)/sizeof (Real));
Array<Real> quantsl;
Array<Real> quantsr;
Array<Quant_score> qscores;
- for(int l =0; l < quantsl.size(); l++)
- for(int r =0; r < quantsr.size(); r++)
+ for (int l =0; l < quantsl.size (); l++)
+ for (int r =0; r < quantsr.size (); r++)
{
Quant_score qs;
qs.yl = quantsl[l];
}
- SCM score_funcs = me->get_grob_property("quant-score-functions");
+ SCM score_funcs = me->get_grob_property ("quant-score-functions");
for (SCM s = score_funcs; gh_pair_p (s); s = gh_cdr (s))
{
SCM f = gh_car (s);
- for (int i = qscores.size(); i--;)
+ for (int i = qscores.size (); i--;)
{
// best scores < 30;
// if (qscores[i].demerits < 1000)
if (qscores[i].demerits < 100)
{
SCM score = gh_call3 (f,
- me->self_scm(),
+ me->self_scm (),
gh_double2scm (qscores[i].yl),
gh_double2scm (qscores[i].yr));
Real best = 1e6;
int best_idx = -1;
- for (int i = qscores.size(); i--;)
+ for (int i = qscores.size (); i--;)
{
if (qscores[i].demerits < best)
{
SCM
Beam::score_slopes_dy (SCM smob, SCM syl, SCM syr)
{
- Grob*me = unsmob_grob(smob);
+ Grob*me = unsmob_grob (smob);
Real yl = gh_scm2double (syl);
Real yr = gh_scm2double (syr);
Real dy = yr - yl;
- SCM sdy = me->get_grob_property("least-squares-dy");
+ SCM sdy = me->get_grob_property ("least-squares-dy");
SCM posns = me->get_grob_property ("positions");
Real dy_mus = gh_number_p (sdy) ? gh_scm2double (sdy) : 0.0;
- Real dy_damp = - gh_scm2double (gh_car(posns)) + gh_scm2double (gh_cdr (posns));
+ Real dy_damp = - gh_scm2double (gh_car (posns)) + gh_scm2double (gh_cdr (posns));
Real dem = 0.0;
if (sign (dy_damp) != sign (dy))
dem += 800;
}
- dem += 400* (0 >? (fabs(dy) - fabs(dy_mus)));
+ dem += 400* (0 >? (fabs (dy) - fabs (dy_mus)));
- dem += shrink_extra_weight (fabs (dy_damp) - fabs(dy))* 10;
- return gh_double2scm (dem);
+ dem += shrink_extra_weight (fabs (dy_damp) - fabs (dy))* 10;
+ return gh_double2scm (dem);
}
MAKE_SCHEME_CALLBACK (Beam, score_stem_lengths, 3);
SCM
Beam::score_stem_lengths (SCM smob, SCM syl, SCM syr)
{
- Grob*me = unsmob_grob(smob);
+ Grob*me = unsmob_grob (smob);
Real yl = gh_scm2double (syl);
Real yr = gh_scm2double (syr);
if (Stem::invisible_b (s))
continue;
- Real current_y = calc_stem_y_f (me, s, Interval(yl,yr));
+ Real current_y = calc_stem_y (me, s, Interval (yl, yr));
Stem_info info = Stem::calc_stem_info (s);
Direction d = Directional_element_interface::get (s);
- demerit_score += 500 * ( 0 >? (info.miny_f_ - d*current_y));
- demerit_score += 500 * ( 0 >? (d * current_y - info.maxy_f_));
+ demerit_score += 500 * ( 0 >? (info.min_y - d * current_y));
+ demerit_score += 500 * ( 0 >? (d * current_y - info.max_y));
- demerit_score += 5 * shrink_extra_weight (d * current_y - info.idealy_f_);
+ demerit_score += 5 * shrink_extra_weight (d * current_y - info.ideal_y);
}
- demerit_score *= 2.0 /stems.size();
+ demerit_score *= 2.0 /stems.size ();
return gh_double2scm (demerit_score);
}
static Real
my_modf (Real x)
{
- return x - floor(x);
+ return x - floor (x);
}
SCM
Beam::score_forbidden_quants (SCM smob, SCM syl, SCM syr)
{
- Grob*me = unsmob_grob(smob);
+ Grob*me = unsmob_grob (smob);
Real yl = gh_scm2double (syl);
Real yr = gh_scm2double (syr);
Real dy = yr - yl;
Real rad = Staff_symbol_referencer::staff_radius (me);
Real dem = 0.0;
- if (fabs (yl) < rad && fabs( my_modf(yl) - 0.5) < 1e-3)
+ if (fabs (yl) < rad && fabs ( my_modf (yl) - 0.5) < 1e-3)
dem += 1000;
- if (fabs (yr) < rad && fabs( my_modf(yr) - 0.5) < 1e-3)
+ if (fabs (yr) < rad && fabs ( my_modf (yr) - 0.5) < 1e-3)
dem += 1000;
// todo: use multiplicity of outer stems.
if (multiplicity >= 2)
{
- Real slt = me->paper_l()->get_var("stafflinethickness");
- Real ss = Staff_symbol_referencer::staff_space(me);
+ Real slt = me->paper_l ()->get_var ("stafflinethickness");
+ Real ss = Staff_symbol_referencer::staff_space (me);
Real thickness = gh_scm2double (me->get_grob_property ("thickness"))
* ss;
-
- Real beam_space= (2*ss + slt - 3 *thickness) / 2.0;
- if (multiplicity >= 4)
- {
- beam_space = (3*ss + slt - 4 * thickness) /3.0;
- }
-
+
+ Real interbeam = multiplicity < 4
+ ? (2*ss + slt - thickness) / 2.0
+ : (3*ss + slt - thickness) / 3.0;
+
Real straddle = 0.0;
Real sit = (thickness - slt) / 2;
Real inter = 0.5;
Real hang = 1.0 - (thickness - slt) / 2;
Direction dir = Directional_element_interface::get (me);
- if (fabs (yl - dir * (beam_space + thickness)) < rad
+ if (fabs (yl - dir * interbeam) < rad
&& fabs (my_modf (yl) - inter) < 1e-3)
dem += 15;
- if (fabs (yr - dir * (beam_space + thickness)) < rad
+ if (fabs (yr - dir * interbeam) < rad
&& fabs (my_modf (yr) - inter) < 1e-3)
dem += 15;
// hmm, without Interval/Drul_array, you get ~ 4x same code...
- if (fabs (yl - dir * (beam_space + thickness)) < rad + inter)
+ if (fabs (yl - dir * interbeam) < rad + inter)
{
if (dir == UP && dy <= 1e-3
&& fabs (my_modf (yl) - sit) < 1e-3)
dem += 15;
}
- if (fabs (yr - dir * (beam_space + thickness)) < rad + inter)
+ if (fabs (yr - dir * interbeam) < rad + inter)
{
if (dir == UP && dy >= 1e-3
&& fabs (my_modf (yr) - sit) < 1e-3)
&& fabs (my_modf (yr) - hang) < 1e-3)
dem += 15;
}
-
+
if (multiplicity >= 3)
{
- if (fabs (yl - 2 * dir * (beam_space + thickness)) < rad + inter)
+ if (fabs (yl - 2 * dir * interbeam) < rad + inter)
{
if (dir == UP && dy <= 1e-3
&& fabs (my_modf (yl) - straddle) < 1e-3)
dem += 15;
}
- if (fabs (yr - 2 * dir * (beam_space + thickness)) < rad + inter)
+ if (fabs (yr - 2 * dir * interbeam) < rad + inter)
{
if (dir == UP && dy >= 1e-3
&& fabs (my_modf (yr) - straddle) < 1e-3)
Direction dir = Directional_element_interface::get (me);
- Interval ideal (Stem::calc_stem_info (first_visible_stem (me)).idealy_f_,
- Stem::calc_stem_info (last_visible_stem (me)).idealy_f_);
+ Interval ideal (Stem::calc_stem_info (first_visible_stem (me)).ideal_y,
+ Stem::calc_stem_info (last_visible_stem (me)).ideal_y);
if (!ideal.delta ())
{
/* Make simple beam on middle line have small tilt */
if (!ideal[LEFT] && chord.delta () && count == 2)
{
- Direction d = (Direction)(sign (chord.delta ()) * dir);
+ Direction d = (Direction) (sign (chord.delta ()) * dir);
pos[d] = gh_scm2double (me->get_grob_property ("thickness")) / 2
* dir;
pos[-d] = - pos[d];
if (Stem::invisible_b (s))
continue;
ideals.push (Offset (s->relative_coordinate (0, X_AXIS) - x0,
- Stem::calc_stem_info (s).idealy_f_));
+ Stem::calc_stem_info (s).ideal_y));
}
Real y;
Real dydx;
return SCM_UNSPECIFIED;
}
-/* Prevent interference from stafflines. */
-Interval
-Beam::quantise_interval (Grob *me, Interval pos, Direction quant_dir)
-{
- int multiplicity = get_multiplicity (me);
-
- Real staff_space = Staff_symbol_referencer::staff_space (me);
- Real thick = me->paper_l ()->get_var ("stafflinethickness");
- Direction dir = Directional_element_interface::get (me);
- Real dy = pos.delta ();
-
- Drul_array<Interval> bounds;
- Direction d = LEFT;
- do
- {
- SCM proc = d == LEFT
- ? me->get_grob_property ("left-position-quant-function")
- : me->get_grob_property ("right-position-quant-function");
-
- SCM quants = scm_apply (proc,
- me->self_scm (),
- scm_list_n (gh_int2scm (multiplicity),
- gh_double2scm (dir),
- gh_double2scm (dy),
- gh_double2scm (thick / staff_space),
- /* HUH? */
- SCM_EOL,
- SCM_UNDEFINED));
-
- Array<Real> a;
- for (SCM i = quants; gh_pair_p (i); i = ly_cdr (i))
- a.push (gh_scm2double (ly_car (i)));
-
- if (a.size () <= 1)
- return pos;
-
- bounds[d] = quantise_iv (a, pos[d]*dir/staff_space) * staff_space;
- }
- while (flip (&d) != LEFT);
-
- Real ady = abs (dy);
-
- // quant direction hints disabled for now
- int q = 0;//(int)quant_dir;
-
- /* TODO: make smart choice, find best left/right quants pair.
-
- Slope should never be steeper than least_squares (before damping)
- (save that value?)
- Slope should never be reduced to zero.
- */
- SCM s = me->get_grob_property ("least-squares-dy");
- Real lsdy = gh_number_p (s) ? gh_scm2double (s) : 0;
-
- // Interval qpos (0, 1000 * sign (dy));
- Interval qpos;
- Real epsilon = staff_space / 10;
- Direction ldir = LEFT;
- do
- {
- Direction rdir = LEFT;
- do
- {
- Interval i (bounds[LEFT][ldir]*dir, bounds[RIGHT][rdir]*dir);
- if ((!lsdy
- || (abs (i.delta ()) <= abs (lsdy) + epsilon
- && sign (i.delta ()) == sign (lsdy)))
- && (abs (abs (i.delta ()) - ady)
- <= abs (abs (qpos.delta ()) - ady))
- && sign (i.delta ()) == sign (pos.delta ())
- && (!q
- || (i[LEFT]*q >= pos[LEFT]*q && i[RIGHT]*q
- >= pos[RIGHT]*q)))
- qpos = i;
- }
- while (flip (&rdir) != LEFT);
- }
- while (flip (&ldir) != LEFT);
-
- return qpos;
-}
-
-
-/* Quantise vertical position (left and right) of beam.
- Generalisation of [Ross]. */
-MAKE_SCHEME_CALLBACK (Beam, quantise_position, 1);
-SCM
-Beam::quantise_position (SCM smob)
-{
- Grob *me = unsmob_grob (smob);
-
- Interval pos = ly_scm2interval (me->get_grob_property ("positions"));
- Real y_shift = check_stem_length_f (me, pos);
- pos += y_shift;
- Real staff_space = Staff_symbol_referencer::staff_space (me);
-
- Direction dir = Directional_element_interface::get (me);
- for (int i = 0; i < 10; i++)
- {
- Interval qpos = quantise_interval (me, pos, CENTER);
- // how to check for uninitised interval, (inf, -inf)?
- if (qpos[LEFT] < 1000)
- {
- y_shift = check_stem_length_f (me, qpos);
- if (y_shift * dir < staff_space / 2)
- {
- pos = qpos;
- break;
- }
- }
- pos += ((i + 1) * ((i % 2) * -2 + 1)) * dir * staff_space / 4;
- }
-
-
- me->set_grob_property ("positions", ly_interval2scm (pos));
- set_stem_lengths (me);
-
-#if 0
- pos = ly_scm2interval (me->get_grob_property ("positions"));
-
- y_shift = check_stem_length_f (me, pos);
-
- Real half_space = Staff_symbol_referencer::staff_space (me) / 2;
- /* HMMM */
- if (y_shift > half_space / 4)
- {
- pos += y_shift;
- int quant_dir = 0;
- /* for significantly lengthened or shortened stems,
- request quanting the other way.
- HMMM */
- if (abs (y_shift) > half_space / 2)
- quant_dir = sign (y_shift) * Directional_element_interface::get (me);
- pos = quantise_interval (me, pos, (Direction)quant_dir);
- }
-
- me->set_grob_property ("positions", ly_interval2scm (pos));
-#endif
-
- return SCM_UNSPECIFIED;
-}
-
MAKE_SCHEME_CALLBACK (Beam, end_after_line_breaking, 1);
SCM
Beam::end_after_line_breaking (SCM smob)
in POS, and for stem S.
*/
Real
-Beam::calc_stem_y_f (Grob *me, Item* s, Interval pos)
+Beam::calc_stem_y (Grob *me, Item* s, Interval pos)
{
int beam_multiplicity = get_multiplicity (me);
int stem_multiplicity = (Stem::flag_i (s) - 2) >? 0;
- SCM space_proc = me->get_grob_property ("space-function");
- SCM space = gh_call1 (space_proc, gh_int2scm (beam_multiplicity));
-
Real thick = gh_scm2double (me->get_grob_property ("thickness"));
- Real interbeam_f = gh_scm2double (space);
+ Real interbeam = get_interbeam (me);
// ugh -> use commonx
Real x0 = first_visible_stem (me)->relative_coordinate (0, X_AXIS);
/* knee */
if (dir!= sdir)
{
- stem_y -= dir * (thick / 2 + (beam_multiplicity - 1) * interbeam_f);
+ stem_y -= dir * (thick / 2 + (beam_multiplicity - 1) * interbeam);
// huh, why not for first visible?
if (Staff_symbol_referencer::staff_symbol_l (s)
!= Staff_symbol_referencer::staff_symbol_l (last_visible_stem (me)))
stem_y += Directional_element_interface::get (me)
- * (beam_multiplicity - stem_multiplicity) * interbeam_f;
+ * (beam_multiplicity - stem_multiplicity) * interbeam;
}
return stem_y;
}
-/* Make very sure that we don't have stems that are too short.
- Try our best not to have stems that are too long (think: knees).
-
- Optionally (testing): try to lengthen more, to reach more ideal
- stem lengths */
-Real
-Beam::check_stem_length_f (Grob *me, Interval pos)
-{
- Real shorten = 0;
- Real lengthen = 0;
- Direction dir = Directional_element_interface::get (me);
-
- Link_array<Item> stems=
- Pointer_group_interface__extract_grobs (me, (Item*)0, "stems");
-
- bool knee = false;
- int ideal_lengthen_count = 0;
- Real ideal_lengthen = 0;
- int ideal_shorten_count = 0;
- Real ideal_shorten = 0;
-
- for (int i=0; i < stems.size (); i++)
- {
- Item* s = stems[i];
- if (Stem::invisible_b (s))
- continue;
-
- knee |= dir != Directional_element_interface::get (s);
-
- Real stem_y = calc_stem_y_f (me, s, pos);
-
- stem_y *= dir;
- Stem_info info = Stem::calc_stem_info (s);
-
- shorten = shorten <? info.maxy_f_ - stem_y;
- lengthen = lengthen >? info.miny_f_ - stem_y;
-
- if (info.idealy_f_ - stem_y > 0)
- {
-#if 0
- ideal_lengthen += info.idealy_f_ - stem_y;
- ideal_lengthen_count++;
-#else
- ideal_lengthen = ideal_lengthen >? info.idealy_f_ - stem_y;
- ideal_lengthen_count = 1;
-#endif
- }
- else if (info.idealy_f_ - stem_y < 0)
- {
-#if 0
- ideal_shorten += info.idealy_f_ - stem_y;
- ideal_shorten_count++;
-#else
- ideal_shorten = ideal_shorten <? info.idealy_f_ - stem_y;
- ideal_shorten_count = 1;
-#endif
- }
- }
-
- if (lengthen && shorten)
- me->warning (_ ("weird beam vertical offset"));
-
- if (ideal_lengthen_count)
- lengthen = (ideal_lengthen / ideal_lengthen_count) >? lengthen;
- if (knee && ideal_shorten_count)
- shorten = (ideal_shorten / ideal_shorten_count) <? shorten;
-
- if (lengthen && shorten)
- return dir * (lengthen + shorten);
-
- return dir * (shorten ? shorten : lengthen);
-}
-
/*
Hmm. At this time, beam position and slope are determined. Maybe,
stem directions and length should set to relative to the chord's
if (Stem::invisible_b (s))
continue;
- Real stem_y = calc_stem_y_f (me, s, pos);
+ Real stem_y = calc_stem_y (me, s, pos);
// doesn't play well with dvips
if (ps_testing)
{
// ugh -> use commonx
if ((next
- && !(next->relative_coordinate (0, X_AXIS)
+ && ! (next->relative_coordinate (0, X_AXIS)
> here->relative_coordinate (0, X_AXIS)))
|| (prev
- && !(prev->relative_coordinate (0, X_AXIS)
+ && ! (prev->relative_coordinate (0, X_AXIS)
< here->relative_coordinate (0, X_AXIS))))
programming_error ("Beams are not left-to-right");
- int multiplicity = get_multiplicity (me);
-
- SCM space_proc = me->get_grob_property ("space-function");
- SCM space = gh_call1 (space_proc, gh_int2scm (multiplicity));
-
Real thick = gh_scm2double (me->get_grob_property ("thickness"));
- Real interbeam_f = gh_scm2double (space);
-
- Real bdy = interbeam_f;
+ Real bdy = get_interbeam (me);
Molecule leftbeams;
Molecule rightbeams;
String str;
if (1)
{
- str += to_str (gh_scm2int (me->get_grob_property ("best-idx")));
+ str += to_str (gh_scm2int (me->get_grob_property ("best-idx")));
str += ":";
}
str += to_str (gh_scm2double (me->get_grob_property ("quant-score")),
SCM properties = Font_interface::font_alist_chain (me);
- Molecule tm = Text_item::text2molecule (me, gh_str02scm (str.ch_C()), properties);
+ Molecule tm = Text_item::text2molecule (me, gh_str02scm (str.ch_C ()), properties);
mol.add_at_edge (Y_AXIS, UP, tm, 5.0);
}
Direction d = Stem::get_direction (stem);
Real beamy = (stem->relative_coordinate (0, X_AXIS) - x0) * dydx + pos[LEFT];
- Real staff_space = Staff_symbol_referencer::staff_space (rest);
+ Real staff_space = Staff_symbol_referencer::staff_space (rest);
Real rest_dim = rest->extent (rest, Y_AXIS)[d]*2.0 / staff_space; // refp??
{
Stem_info si ;
- si.idealy_f_ = gh_scm2double (gh_car (scm_info));
- si.maxy_f_ = gh_scm2double (gh_cadr (scm_info));
- si.miny_f_ = gh_scm2double (gh_caddr (scm_info));
+ si.ideal_y = gh_scm2double (gh_car (scm_info));
+ si.max_y = gh_scm2double (gh_cadr (scm_info));
+ si.min_y = gh_scm2double (gh_caddr (scm_info));
return si;
}
Real staff_space = Staff_symbol_referencer::staff_space (me);
Real half_space = staff_space / 2;
+
int multiplicity = Beam::get_multiplicity (beam);
-
-
- SCM space_proc = beam->get_grob_property ("space-function");
- SCM space = gh_call1 (space_proc, gh_int2scm (multiplicity));
- Real interbeam_f = gh_scm2double (space) * staff_space;
+ Real interbeam_f = Beam::get_interbeam (beam);
Real thick = gh_scm2double (beam->get_grob_property ("thickness"));
Stem_info info;
- info.idealy_f_ = chord_start_f (me);
+ info.ideal_y = chord_start_f (me);
// for simplicity, we calculate as if dir == UP
- info.idealy_f_ *= beam_dir;
+ info.ideal_y *= beam_dir;
SCM grace_prop = me->get_grob_property ("grace");
bool grace_b = to_boolean (grace_prop);
{
if (multiplicity)
{
- info.idealy_f_ += thick + (multiplicity - 1) * interbeam_f;
+ info.ideal_y += thick + (multiplicity - 1) * interbeam_f;
}
- info.miny_f_ = info.idealy_f_;
- info.maxy_f_ = 1000; // INT_MAX;
+ info.min_y = info.ideal_y;
+ info.max_y = 1000; // INT_MAX;
- info.idealy_f_ += stem_length;
- info.miny_f_ += minimum_length;
+ info.ideal_y += stem_length;
+ info.min_y += minimum_length;
/*
lowest beam of (UP) beam must never be lower than second staffline
staffline
lowest beam of (UP) beam must never be lower than second staffline
*/
- info.miny_f_ =
- info.miny_f_ >? 0
+ info.min_y =
+ info.min_y >? 0
>? (- 2 * half_space - thick
+ (multiplicity > 0) * thick
+ interbeam_f * (multiplicity - 1));
else
/* knee */
{
- info.idealy_f_ -= thick;
- info.maxy_f_ = info.idealy_f_;
- info.miny_f_ = - 1000 ; // INT_MAX;
+ info.ideal_y -= thick;
+ info.max_y = info.ideal_y;
+ info.min_y = - 1000 ; // INT_MAX;
- info.idealy_f_ -= stem_length;
- info.maxy_f_ -= minimum_length;
+ info.ideal_y -= stem_length;
+ info.max_y -= minimum_length;
}
- info.idealy_f_ = (info.maxy_f_ <? info.idealy_f_) >? info.miny_f_;
+ info.ideal_y = (info.max_y <? info.ideal_y) >? info.min_y;
s = beam->get_grob_property ("shorten");
if (gh_number_p (s))
- info.idealy_f_ -= gh_scm2double (s);
+ info.ideal_y -= gh_scm2double (s);
- Grob *common = me->common_refpoint (beam, Y_AXIS);
+ Grob *common = me->common_refpoint (beam, Y_AXIS);
Real interstaff_f = beam_dir *
- (me->relative_coordinate (common, Y_AXIS)
+ (me->relative_coordinate (common, Y_AXIS)
- beam->relative_coordinate (common, Y_AXIS));
-
- info.idealy_f_ += interstaff_f;
- info.miny_f_ += interstaff_f;
- info.maxy_f_ += interstaff_f ;
+
+ info.ideal_y += interstaff_f;
+ info.min_y += interstaff_f;
+ info.max_y += interstaff_f ;
me->set_grob_property ("stem-info",
- scm_list_n (gh_double2scm (info.idealy_f_),
- gh_double2scm (info.maxy_f_ ),
- gh_double2scm (info.miny_f_),
+ scm_list_n (gh_double2scm (info.ideal_y),
+ gh_double2scm (info.max_y),
+ gh_double2scm (info.min_y),
SCM_UNDEFINED));
return info;
;;;; (c) 2000--2001 Jan Nieuwenhuizen <janneke@gnu.org>
;;;;
-(define (default-beam-space-function multiplicity)
- (if (<= multiplicity 3) 0.816 0.844)
- )
-
;;
;; width in staff space.
;;
(cond
((eq? type 1) 1.98)
((eq? type 1) 1.65) ;; FIXME: check what this should be and why
- (else 1.32)
- ))
-
-
-;; This is a mess : global namespace pollution. We should wait
-;; till guile has proper toplevel environment support.
-
-
-;; Beams should be prevented to conflict with the stafflines,
-;; especially at small slopes
-;; ----------------------------------------------------------
-;; ########
-;; ########
-;; ########
-;; --------------########------------------------------------
-;; ########
-;;
-;; hang straddle sit inter hang
-
-;; inter seems to be a modern quirk, we don't use that
-
-;; two popular veritcal beam quantings
-;; see params.ly: #'beam-vertical-quants
-
-
-(define (default-beam-pos-quants beam multiplicity dy staff-line)
- (let* ((beam-straddle 0)
- (thick (ly-get-grob-property beam 'thickness))
- (beam-sit (/ (- thick staff-line) 2))
- (beam-hang (- 1 (/ (- thick staff-line) 2)))
- (quants (list beam-hang))
- )
-
- (if (or (<= multiplicity 1) (>= (abs dy) (/ staff-line 2)))
- (set! quants (cons beam-sit quants)))
- (if (or (<= multiplicity 2) (>= (abs dy) (/ staff-line 2)))
- (set! quants (cons beam-straddle quants)))
- ;; period: 1 (staff-space)
- (append quants (list (+ 1 (car quants))))))
-
-(define (default-left-beam-pos-quants beam multiplicity dir dy staff-line)
- (default-beam-pos-quants beam multiplicity 1 staff-line))
-;;
-(define (foo beam multiplicity dir dy staff-line)
- (let* ((beam-straddle 0)
- (thick (ly-get-grob-property beam 'thickness))
- (beam-sit (/ (- thick staff-line) 2))
- (beam-hang (- 1 (/ (- thick staff-line) 2)))
- (quants '())
- )
-
- (if (or (<= multiplicity 1)
- (and (not (equal? dir 1))
- (not (< dy 0))))
- (set! quants (cons beam-sit quants)))
- (if (or (<= multiplicity 1)
- (and (not (equal? dir -1))
- (not (> dy 0))))
- (set! quants (cons beam-hang quants)))
- (if (or (<= multiplicity 2) (>= (abs dy) (/ staff-line 2)))
- (set! quants (cons beam-straddle quants)))
- ;; period: 1 (staff-space)
- (append quants (list (+ 1 (car quants))))))
-
-(define (default-right-beam-pos-quants beam multiplicity dir dy staff-line)
- (default-beam-pos-quants beam multiplicity 1 staff-line))
-;;
-(define (foo beam multiplicity dir dy staff-line)
- (let* ((beam-straddle 0)
- (thick (ly-get-grob-property beam 'thickness))
- (beam-sit (/ (- thick staff-line) 2))
- (beam-hang (- 1 (/ (- thick staff-line) 2)))
- (quants '())
- )
-
-
- (if (or (<= multiplicity 1)
- (and (not (equal? dir 1))
- (not (> dy 0))))
- (set! quants (cons beam-sit quants)))
- (if (or (<= multiplicity 1)
- (and (not (equal? dir -1))
- (not (< dy 0))))
- (set! quants (cons beam-hang quants)))
- (if (or (<= multiplicity 2) (>= (abs dy) (/ staff-line 2)))
- (set! quants (cons beam-straddle quants)))
- ;; period: 1 (staff-space)
- (append quants (list (+ 1 (car quants))))))
-
-(define (beam-traditional-pos-quants beam multiplicity dy staff-line)
- (let* ((beam-straddle 0)
- (thick (ly-get-grob-property beam 'thickness))
- (beam-sit (/ (- thick staff-line) 2))
- (beam-hang (- 1 (/ (- thick staff-line) 2)))
- (quants '())
- )
- (if (>= dy (/ staff-line -2))
- (set! quants (cons beam-hang quants)))
- (if (and (<= multiplicity 1) (<= dy (/ staff-line 2)))
- (set! quants (cons beam-sit quants)))
- (if (or (<= multiplicity 2) (>= (abs dy) (/ staff-line 2)))
- (set! quants (cons beam-straddle quants)))
- ;; period: 1 (staff-space)
- (append quants (list (+ 1 (car quants))))))
-
+ (else 1.32)))
;; There are several ways to calculate the direction of a beam
;;
;; * majority: number count of up or down notes
;; * mean : mean centre distance of all notes
;; * median : mean centre distance weighted per note
+;;
+;; [Ross] states that the majority of the notes dictates the
+;; direction (and not the mean of "center distance")
+;;
+;; But is that because it really looks better, or because he wants
+;; to provide some real simple hands-on rules?
+;;
+;; We have our doubts, so we simply provide all sensible alternatives.
(define (dir-compare up down)
(sign (- up down)))
(dir-compare (/ (car total) (car count)) (/ (cdr total) (cdr count)))
(dir-compare (car count) (cdr count))))
-
-
-;; [Ross] states that the majority of the notes dictates the
-;; direction (and not the mean of "center distance")
-;;
-;; But is that because it really looks better, or because he wants
-;; to provide some real simple hands-on rules?
-;;
-;; We have our doubts, so we simply provide all sensible alternatives.
-
-;; array index multiplicity, last if index>size
-;; beamed stems
-
-
-;; TODO
-;; - take #forced stems into account (now done in C++)?
-;; - take staff-position of chord or beam into account
-