/*
beam.cc -- implement Beam
-
+
source file of the GNU LilyPond music typesetter
-
- (c) 1997--2001 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>
+
*/
/*
- [TODO]
+TODO:
- -* shorter! (now +- 1000 lines)
+ * Use Number_pair i.s.o Interval to represent (yl, yr).
- -* less hairy code
+ - Determine auto knees based on positions if it's set by the user.
+
+
+Notes:
+
+
+ - Stems run to the Y-center of the beam.
- */
+ - beam_translation is the offset between Y centers of the beam.
+
+*/
#include <math.h> // tanh.
#include "spanner.hh"
#include "warn.hh"
+
+#define DEBUG_QUANTING 0
+
+
+#if DEBUG_QUANTING
+#include "text-item.hh" // debug output.
+#include "font-interface.hh" // debug output.
+#endif
+
+
void
-Beam::add_stem (Grob*me, Grob*s)
+Beam::add_stem (Grob *me, Grob *s)
{
- Pointer_group_interface:: add_element (me, "stems", s);
+ Pointer_group_interface::add_grob (me, ly_symbol2scm ("stems"), s);
s->add_dependency (me);
- assert (!Stem::beam_l (s));
+ assert (!Stem::get_beam (s));
s->set_grob_property ("beam", me->self_scm ());
add_bound_item (dynamic_cast<Spanner*> (me), dynamic_cast<Item*> (s));
}
+
+Real
+Beam::get_thickness (Grob * me)
+{
+ SCM th = me->get_grob_property ("thickness");
+ if (gh_number_p (th))
+ return gh_scm2double (th)* Staff_symbol_referencer::staff_space (me);
+ else
+ return 0.0;
+}
+
+/* Return the translation between 2 adjoining beams. */
+Real
+Beam::get_beam_translation (Grob *me)
+{
+ SCM func = me->get_grob_property ("space-function");
+ SCM s = gh_call2 (func, me->self_scm (), scm_int2num (get_beam_count (me)));
+ return gh_scm2double (s);
+}
+
+/* Maximum beam_count. */
int
-Beam::get_multiplicity (Grob*me)
+Beam::get_beam_count (Grob *me)
{
int m = 0;
for (SCM s = me->get_grob_property ("stems"); gh_pair_p (s); s = ly_cdr (s))
{
- Grob * sc = unsmob_grob (ly_car (s));
-
- if (Stem::has_interface (sc))
- m = m >? Stem::beam_count (sc,LEFT) >? Stem::beam_count (sc,RIGHT);
+ Grob *stem = unsmob_grob (ly_car (s));
+ m = m >? (Stem::beam_multiplicity (stem).length () + 1);
}
return m;
}
-/*
- After pre-processing all directions should be set.
- Several post-processing routines (stem, slur, script) need stem/beam
- direction.
- Currenly, this means that beam has set all stem's directions.
- [Alternatively, stems could set its own directions, according to
- their beam, during 'final-pre-processing'.]
- */
-MAKE_SCHEME_CALLBACK (Beam,before_line_breaking,1);
+MAKE_SCHEME_CALLBACK (Beam, space_function, 2);
SCM
-Beam::before_line_breaking (SCM smob)
+Beam::space_function (SCM smob, SCM beam_count)
{
- Grob * me = unsmob_grob (smob);
+ Grob *me = unsmob_grob (smob);
+
+ Real staff_space = Staff_symbol_referencer::staff_space (me);
+ Real line = me->get_paper ()->get_var ("linethickness");
+ Real thickness = get_thickness (me);
+
+ Real beam_translation = gh_scm2int (beam_count) < 4
+ ? (2*staff_space + line - thickness) / 2.0
+ : (3*staff_space + line - thickness) / 3.0;
+
+ return gh_double2scm (beam_translation);
+}
- // Why?
- /*
- Why what? Why the warning (beams with less than 2 stems are
- degenerate beams, should never happen), or why would this ever
- happen (don't know). */
- if (visible_stem_count (me) < 2)
+
+/* After pre-processing all directions should be set.
+ Several post-processing routines (stem, slur, script) need stem/beam
+ direction.
+ Currenly, this means that beam has set all stem's directions.
+ [Alternatively, stems could set its own directions, according to
+ their beam, during 'final-pre-processing'.] */
+MAKE_SCHEME_CALLBACK (Beam, before_line_breaking, 1);
+SCM
+Beam::before_line_breaking (SCM smob)
+{
+ Grob *me = unsmob_grob (smob);
+
+ /* Beams with less than 2 two stems don't make much sense, but could happen
+ when you do
+
+ [r8 c8 r8].
+
+ For a beam that only has one stem, we try to do some disappearance magic:
+ we revert the flag, and move on to The Eternal Engraving Fields. */
+
+ int count = visible_stem_count (me);
+ if (count < 2)
{
- warning (_ ("beam has less than two stems"));
+ me->warning (_ ("beam has less than two visible stems"));
+
+ SCM stems = me->get_grob_property ("stems");
+ if (scm_ilength (stems) == 1)
+ {
+ me->warning (_ ("Beam has less than two stems. Removing beam."));
+
+ unsmob_grob (gh_car (stems))->set_grob_property ("beam", SCM_EOL);
+ me->suicide ();
+
+ return SCM_UNSPECIFIED;
+ }
+ else if (scm_ilength (stems) == 0)
+ {
+ me->suicide ();
+ return SCM_UNSPECIFIED;
+ }
}
- if (visible_stem_count (me) >= 1)
+ if (count >= 1)
{
- if (!Directional_element_interface::get (me))
- Directional_element_interface::set (me, get_default_dir (me));
-
+ Direction d = get_default_dir (me);
+
consider_auto_knees (me);
- set_stem_directions (me);
+ set_stem_directions (me, d);
+
+ connect_beams (me);
+
set_stem_shorten (me);
}
+
return SCM_EOL;
}
+
+/*
+ We want a maximal number of shared beams, but if there is choice, we
+ take the one that is closest to the end of the stem. This is for situations like
+
+ x
+ |
+ |
+ |===|
+ |=
+ |
+ x
+
+
+ */
+int
+position_with_maximal_common_beams (SCM left_beaming, SCM right_beaming,
+ Direction left_dir,
+ Direction right_dir)
+{
+ Slice lslice = int_list_to_slice (gh_cdr (left_beaming));
+
+ int best_count = 0;
+ int best_start = 0;
+ for (int i = lslice[-left_dir];
+ (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))
+ {
+ int k = - right_dir * gh_scm2int (gh_car (s)) + i;
+ if (scm_memq (scm_int2num (k), left_beaming) != SCM_BOOL_F)
+ count ++;
+ }
+
+ if (count >= best_count)
+ {
+ best_count = count;
+ best_start = i;
+ }
+ }
+
+ return best_start;
+}
+
+void
+Beam::connect_beams (Grob *me)
+{
+ Link_array<Grob> stems=
+ Pointer_group_interface__extract_grobs (me, (Grob*)0, "stems");
+
+ Slice last_int;
+ last_int.set_empty();
+ SCM last_beaming = SCM_EOL;
+ Direction last_dir = CENTER;
+ for (int i = 0; i< stems.size(); i++)
+ {
+ Grob *this_stem = stems[i];
+ SCM this_beaming = this_stem->get_grob_property ("beaming");
+
+ Direction this_dir = Directional_element_interface::get(this_stem);
+ if (i > 0)
+ {
+ int start_point = position_with_maximal_common_beams
+ (last_beaming, this_beaming,
+ last_dir, this_dir);
+
+ Direction d = LEFT;
+ Slice new_slice ;
+ do
+ {
+ if (d == RIGHT && i == stems.size()-1)
+ continue;
+
+ new_slice.set_empty();
+ SCM s = index_get_cell (this_beaming, d);
+ for (; gh_pair_p (s); s = gh_cdr (s))
+ {
+ int new_beam_pos =
+ start_point - this_dir * gh_scm2int (gh_car (s));
+
+ new_slice.add_point (new_beam_pos);
+ gh_set_car_x (s, scm_int2num (new_beam_pos));
+ }
+
+
+ }
+ while (flip (&d) != LEFT);
+
+ if (!new_slice.empty_b())
+ last_int = new_slice;
+ }
+ else
+ {
+ gh_set_car_x ( this_beaming, SCM_EOL);
+ SCM s = gh_cdr (this_beaming);
+ for (; gh_pair_p (s); s = gh_cdr (s))
+ {
+ int np = - this_dir * gh_scm2int (gh_car(s));
+ gh_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);
+ }
+
+ if (scm_ilength (gh_cdr (this_beaming)) > 0)
+ {
+ last_beaming = this_beaming;
+ last_dir = this_dir;
+ }
+ }
+ }
+
+MAKE_SCHEME_CALLBACK (Beam, brew_molecule, 1);
+SCM
+Beam::brew_molecule (SCM grob)
+{
+ Grob *me = unsmob_grob (grob);
+ Link_array<Grob> stems=
+ Pointer_group_interface__extract_grobs (me, (Grob*)0, "stems");
+ Grob* xcommon = common_refpoint_of_array (stems, me, X_AXIS);
+
+ Real x0, dx;
+ if (visible_stem_count (me))
+ {
+ // ugh -> use commonx
+ x0 = first_visible_stem (me)->relative_coordinate (xcommon, X_AXIS);
+ dx = last_visible_stem (me)->relative_coordinate (xcommon, X_AXIS) - x0;
+ }
+ else
+ {
+ x0 = stems[0]->relative_coordinate (xcommon, X_AXIS);
+ dx = stems.top ()->relative_coordinate (xcommon, X_AXIS) - x0;
+ }
+
+ SCM posns = me->get_grob_property ("positions");
+ Interval pos;
+ if (!ly_number_pair_p (posns))
+ {
+ programming_error ("No beam posns");
+ pos = Interval (0,0);
+ }
+ else
+ pos= ly_scm2interval (posns);
+
+ Real dy = pos.delta ();
+ Real dydx = dy && dx ? dy/dx : 0;
+
+ Real thick = get_thickness (me);
+ Real bdy = get_beam_translation (me);
+
+ SCM last_beaming = SCM_EOL;;
+ Real last_xposn = -1;
+ Real last_width = -1 ;
+
+
+ SCM gap = me->get_grob_property ("gap");
+ Molecule the_beam;
+ Real lt = me->get_paper ()->get_var ("linethickness");
+ for (int i = 0; i< stems.size(); i++)
+ {
+ Grob * st =stems[i];
+
+ SCM this_beaming = st->get_grob_property ("beaming");
+ Real xposn = st->relative_coordinate (xcommon, X_AXIS);
+ Real stem_width = gh_scm2double (st->get_grob_property ("thickness")) *lt;
+
+ if (i > 0)
+ {
+ SCM left = gh_cdr (last_beaming);
+ SCM right = gh_car (this_beaming);
+
+ Array<int> fullbeams;
+ Array<int> lfliebertjes;
+ Array<int> rfliebertjes;
+
+ for (SCM s = left;
+ gh_pair_p (s); s =gh_cdr (s))
+ {
+ int b = gh_scm2int (gh_car (s));
+ if (scm_memq (gh_car(s), right) != SCM_BOOL_F)
+ {
+ fullbeams.push (b);
+ }
+ else
+ {
+ lfliebertjes.push (b);
+ }
+ }
+ for (SCM s = right;
+ gh_pair_p (s); s =gh_cdr (s))
+ {
+ int b = gh_scm2int (gh_car (s));
+ if (scm_memq (gh_car(s), left) == SCM_BOOL_F)
+ {
+ rfliebertjes.push (b);
+ }
+ }
+
+
+ Real w = xposn - last_xposn;
+ Real stem_offset = 0.0;
+ Real width_corr = 0.0;
+ if (i == 1)
+ {
+ stem_offset -= last_width/2;
+ width_corr += last_width/2;
+ }
+
+ if (i == stems.size() -1)
+ {
+ width_corr += stem_width/2;
+ }
+
+ if (gh_number_p (gap))
+ {
+ Real g = gh_scm2double (gap);
+ stem_offset += g;
+ width_corr -= 2*g;
+ }
+
+ Molecule whole = Lookup::beam (dydx, w + width_corr, thick);
+ for (int j = fullbeams.size(); j--;)
+ {
+ Molecule b (whole);
+ b.translate_axis (last_xposn - x0 + stem_offset, X_AXIS);
+ b.translate_axis (dydx * (last_xposn - x0) + bdy * fullbeams[j], Y_AXIS);
+ the_beam.add_molecule (b);
+ }
+
+ if (lfliebertjes.size() || rfliebertjes.size())
+ {
+
+ Real nw_f;
+ if (!Stem::first_head (st))
+ nw_f = 0;
+ else
+ {
+ int t = Stem::duration_log (st);
+
+ SCM proc = me->get_grob_property ("flag-width-function");
+ SCM result = gh_call1 (proc, scm_int2num (t));
+ nw_f = gh_scm2double (result);
+ }
+
+ /* Half beam should be one note-width,
+ but let's make sure two half-beams never touch */
+
+ Real w = xposn - last_xposn;
+ w = w/2 <? nw_f;
+
+ Molecule half = Lookup::beam (dydx, w, thick);
+ for (int j = lfliebertjes.size(); j--;)
+ {
+ Molecule b (half);
+ b.translate_axis (last_xposn - x0, X_AXIS);
+ b.translate_axis (dydx * (last_xposn-x0) + bdy * lfliebertjes[j], Y_AXIS);
+ the_beam.add_molecule (b);
+ }
+ for (int j = rfliebertjes.size(); j--;)
+ {
+ Molecule b (half);
+ b.translate_axis (xposn - x0 - w , X_AXIS);
+ b.translate_axis (dydx * (xposn-x0 -w) + bdy * rfliebertjes[j], Y_AXIS);
+ the_beam.add_molecule (b);
+ }
+ }
+ }
+
+ last_xposn = xposn;
+ last_width = stem_width;
+ last_beaming = this_beaming;
+ }
+
+ the_beam.translate_axis (x0 - me->relative_coordinate (xcommon, X_AXIS), X_AXIS);
+ the_beam.translate_axis (pos[LEFT], Y_AXIS);
+
+#if (DEBUG_QUANTING)
+ {
+ /*
+ This code prints the demerits for each beam. Perhaps this
+ should be switchable for those who want to twiddle with the
+ parameters.
+ */
+ String str;
+ if (1)
+ {
+ str += to_string (gh_scm2int (me->get_grob_property ("best-idx")));
+ str += ":";
+ }
+ str += to_string (gh_scm2double (me->get_grob_property ("quant-score")),
+ "%.2f");
+
+ SCM properties = Font_interface::font_alist_chain (me);
+
+
+ Molecule tm = Text_item::text2molecule (me, scm_makfrom0str (str.to_str0 ()), properties);
+ the_beam.add_at_edge (Y_AXIS, UP, tm, 5.0);
+ }
+#endif
+
+
+
+ return the_beam.smobbed_copy();
+}
+
+
+
+
Direction
-Beam::get_default_dir (Grob*me)
+Beam::get_default_dir (Grob *me)
{
Drul_array<int> total;
total[UP] = total[DOWN] = 0;
count[UP] = count[DOWN] = 0;
Direction d = DOWN;
- Link_array<Item> stems=
- Pointer_group_interface__extract_elements (me, (Item*)0, "stems");
+ Link_array<Grob> stems=
+ Pointer_group_interface__extract_grobs (me, (Grob*)0, "stems");
for (int i=0; i <stems.size (); i++)
do {
Grob *s = stems[i];
Direction sd = Directional_element_interface::get (s);
- int current = sd ? (1 + d * sd)/2
- : Stem::get_center_distance (s, (Direction)-d);
+
+ int center_distance = int(- d * Stem::head_positions (s) [-d]) >? 0;
+ int current = sd ? (1 + d * sd)/2 : center_distance;
if (current)
{
total[d] += current;
count[d] ++;
}
-
} while (flip (&d) != DOWN);
SCM func = me->get_grob_property ("dir-function");
SCM s = gh_call2 (func,
- gh_cons (gh_int2scm (count[UP]),
- gh_int2scm (count[DOWN])),
- gh_cons (gh_int2scm (total[UP]),
- gh_int2scm (total[DOWN])));
+ gh_cons (scm_int2num (count[UP]),
+ scm_int2num (count[DOWN])),
+ gh_cons (scm_int2num (total[UP]),
+ scm_int2num (total[DOWN])));
if (gh_number_p (s) && gh_scm2int (s))
return to_dir (s);
- /*
- If dir is not determined: get default
- */
+ /* If dir is not determined: get default */
return to_dir (me->get_grob_property ("neutral-direction"));
}
-/*
- Set all stems with non-forced direction to beam direction.
- Urg: non-forced should become `without/with unforced' direction,
- once stem gets cleaned-up.
- */
+/* Set all stems with non-forced direction to beam direction.
+ Urg: non-forced should become `without/with unforced' direction,
+ once stem gets cleaned-up. */
void
-Beam::set_stem_directions (Grob*me)
+Beam::set_stem_directions (Grob *me, Direction d)
{
- Link_array<Item> stems
- =Pointer_group_interface__extract_elements (me, (Item*) 0, "stems");
- Direction d = Directional_element_interface::get (me);
+ Link_array<Grob> stems
+ =Pointer_group_interface__extract_grobs (me, (Grob*) 0, "stems");
for (int i=0; i <stems.size (); i++)
{
Grob *s = stems[i];
- SCM force = s->remove_grob_property ("dir-forced");
- if (!gh_boolean_p (force) || !gh_scm2bool (force))
- Directional_element_interface ::set (s,d);
+
+ SCM forcedir = s->get_grob_property ("direction");
+ if (!to_dir (forcedir))
+ Directional_element_interface::set (s, d);
}
-}
+}
/*
- Simplistic auto-knees; only consider vertical gap between two
- adjacent chords.
+ A union of intervals in the real line.
- `Forced' stem directions are ignored. If you don't want auto-knees,
- don't set, or unset auto-knee-gap.
+ Abysmal performance (quadratic) for large N, hopefully we don't have
+ that large N. In any case, this should probably be rewritten to use
+ a balanced tree.
+ */
+struct Int_set
+{
+ Array<Interval> allowed_regions_;
+
+ Int_set()
+ {
+ set_full();
+ }
+
+ void set_full()
+ {
+ allowed_regions_.clear();
+ Interval s;
+ s.set_full ();
+ allowed_regions_.push (s);
+ }
+
+ void remove_interval (Interval rm)
+ {
+ for (int i = 0; i < allowed_regions_.size(); )
+ {
+ Interval s = rm;
+
+ s.intersect (allowed_regions_[i]);
+
+ if (!s.empty_b ())
+ {
+ Interval before = allowed_regions_[i];
+ Interval after = allowed_regions_[i];
+
+ before[RIGHT] = s[LEFT];
+ after[LEFT] = s[RIGHT];
+
+ if (!before.empty_b() && before.length () > 0.0)
+ {
+ allowed_regions_.insert (before, i);
+ i++;
+ }
+ allowed_regions_.del (i);
+ if (!after.empty_b () && after.length () > 0.0)
+ {
+ allowed_regions_.insert (after, i);
+ i++;
+ }
+ }
+ else
+ i++;
+ }
+ }
+};
+
+
+/*
+ Only try horizontal beams for knees. No reliable detection of
+ anything else is possible here, since we don't know funky-beaming
+ settings, or X-distances (slopes!) People that want sloped
+ knee-beams, should set the directions manually.
*/
void
-Beam::consider_auto_knees (Grob *me)
+Beam::consider_auto_knees (Grob* me)
{
SCM scm = me->get_grob_property ("auto-knee-gap");
+ if (!gh_number_p (scm))
+ return ;
- if (gh_number_p (scm))
- {
- bool knee_b = false;
- Real knee_y = 0;
- Real staff_space = Staff_symbol_referencer::staff_space (me);
- Real gap = gh_scm2double (scm) / staff_space;
-
- Direction d = Directional_element_interface::get (me);
- Link_array<Item> stems=
- Pointer_group_interface__extract_elements (me, (Item*)0, "stems");
-
- Grob *common = me->common_refpoint (stems[0], Y_AXIS);
- for (int i=1; i < stems.size (); i++)
- if (!Stem::invisible_b (stems[i]))
- common = common->common_refpoint (stems[i], Y_AXIS);
-
- int l = 0;
- for (int i=1; i < stems.size (); i++)
- {
- if (!Stem::invisible_b (stems[i-1]))
- l = i - 1;
- if (Stem::invisible_b (stems[l]))
- continue;
- if (Stem::invisible_b (stems[i]))
- continue;
-
- Real left = Stem::extremal_heads (stems[l])[d]
- ->relative_coordinate (common, Y_AXIS);
- Real right = Stem::extremal_heads (stems[i])[-d]
- ->relative_coordinate (common, Y_AXIS);
+ Real threshold = gh_scm2double (scm);
+
+ Int_set gaps;
- Real dy = right - left;
+ gaps.set_full ();
- if (abs (dy) >= gap)
+ Link_array<Grob> stems=
+ Pointer_group_interface__extract_grobs (me, (Grob*)0, "stems");
+
+ Grob *common = common_refpoint_of_array (stems, me, Y_AXIS);
+ Real staff_space = Staff_symbol_referencer::staff_space (me);
+
+ Array<Interval> hps_array;
+ for (int i=0; i < stems.size (); i++)
+ {
+ Grob* stem = stems[i];
+ if (Stem::invisible_b (stem))
+ continue;
+
+ Interval hps = Stem::head_positions (stem);
+ if(!hps.empty_b())
+ {
+ hps[LEFT] += -1;
+ hps[RIGHT] += 1;
+ hps *= staff_space * 0.5 ;
+
+ /*
+ We could subtract beam Y position, but this routine only
+ sets stem directions, a constant shift does not have an
+ influence.
+
+ */
+ hps += stem->relative_coordinate (common, Y_AXIS);
+
+ if (to_dir (stem->get_grob_property ("direction")))
{
- knee_y = (right + left) / 2;
- knee_b = true;
- break;
+ Direction stemdir = to_dir (stem->get_grob_property ("direction"));
+ hps[-stemdir] = - stemdir * infinity_f;
}
}
+ hps_array.push (hps);
+
+ gaps.remove_interval (hps);
+ }
+
+ Interval max_gap;
+ Real max_gap_len =0.0;
+
+ for (int i = gaps.allowed_regions_.size() -1; i >= 0 ; i--)
+ {
+ Interval gap = gaps.allowed_regions_[i];
+
+ /*
+ the outer gaps are not knees.
+ */
+ if (isinf (gap[LEFT]) || isinf(gap[RIGHT]))
+ continue;
- if (knee_b)
+ if (gap.length () >= max_gap_len)
{
- for (int i=0; i < stems.size (); i++)
- {
- if (Stem::invisible_b (stems[i]))
- continue;
- Item *s = stems[i];
- Real y = Stem::extremal_heads (stems[i])[d]
- ->relative_coordinate (common, Y_AXIS);
+ max_gap_len = gap.length();
+ max_gap = gap;
+ }
+ }
- Directional_element_interface::set (s, y < knee_y ? UP : DOWN);
- s->set_grob_property ("dir-forced", SCM_BOOL_T);
- }
+ if (max_gap_len > threshold)
+ {
+ int j = 0;
+ for (int i = 0; i < stems.size(); i++)
+ {
+ Grob* stem = stems[i];
+ if (Stem::invisible_b (stem))
+ continue;
+
+ Interval hps = hps_array[j++];
+
+
+ Direction d = (hps.center () < max_gap.center()) ?
+ UP : DOWN ;
+
+ stem->set_grob_property ("direction", scm_int2num (d));
+
+ hps.intersect (max_gap);
+ assert (hps.empty_b () || hps.length () < 1e-6 );
}
}
}
-/*
- Set stem's shorten property if unset.
+
+
+/* Set stem's shorten property if unset.
+
TODO:
- take some y-position (chord/beam/nearest?) into account
- scmify forced-fraction
- */
+ take some y-position (chord/beam/nearest?) into account
+ scmify forced-fraction
+
+ This is done in beam because the shorten has to be uniform over the
+ entire beam.
+
+*/
void
-Beam::set_stem_shorten (Grob*m)
+Beam::set_stem_shorten (Grob *me)
{
- Spanner*me = dynamic_cast<Spanner*> (m);
-
- Real forced_fraction = forced_stem_count (me) / visible_stem_count (me);
- if (forced_fraction < 0.5)
- return;
+ /*
+ shortening looks silly for x staff beams
+ */
+ if (knee_b(me))
+ return ;
+
+ Real forced_fraction = 1.0 * forced_stem_count (me)
+ / visible_stem_count (me);
- int multiplicity = get_multiplicity (me);
+ int beam_count = get_beam_count (me);
- SCM shorten = me->get_grob_property ("beamed-stem-shorten");
- if (shorten == SCM_EOL)
+ SCM shorten_list = me->get_grob_property ("beamed-stem-shorten");
+ if (shorten_list == SCM_EOL)
return;
- int sz = scm_ilength (shorten);
-
Real staff_space = Staff_symbol_referencer::staff_space (me);
- SCM shorten_elt = scm_list_ref (shorten, gh_int2scm (multiplicity <? (sz - 1)));
+
+ SCM shorten_elt =
+ robust_list_ref (beam_count -1, shorten_list);
Real shorten_f = gh_scm2double (shorten_elt) * staff_space;
- /* cute, but who invented me -- how to customise ? */
- if (forced_fraction < 1)
- shorten_f /= 2;
-
- Link_array<Item> stems=
- Pointer_group_interface__extract_elements (me, (Item*)0, "stems");
+ /* your similar cute comment here */
+ shorten_f *= forced_fraction;
- for (int i=0; i < stems.size (); i++)
- {
- Item* s = stems[i];
- if (Stem::invisible_b (s))
- continue;
- if (gh_number_p (s->get_grob_property ("shorten")))
- s->set_grob_property ("shorten", gh_double2scm (shorten_f));
- }
+ if (shorten_f)
+ me->set_grob_property ("shorten", gh_double2scm (shorten_f));
}
-/*
- Call list of y-dy-callbacks, that handle setting of
- 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.
+/* Call list of y-dy-callbacks, that handle setting of
+ grob-properties
- Because y and dy cannot be calculated and quanted separately, we
- always calculate both, then check for user override.
- */
+*/
MAKE_SCHEME_CALLBACK (Beam, after_line_breaking, 1);
SCM
Beam::after_line_breaking (SCM smob)
{
- Grob * me = unsmob_grob (smob);
+ Grob *me = unsmob_grob (smob);
- me->set_grob_property ("y", gh_double2scm (0));
- me->set_grob_property ("dy", gh_double2scm (0));
+ /* Copy to mutable list. */
+ SCM s = ly_deep_copy (me->get_grob_property ("positions"));
+ me->set_grob_property ("positions", s);
- /* Hmm, callbacks should be called by, a eh, callback mechanism
- somewhere (?), I guess, not by looping here. */
-
- SCM list = me->get_grob_property ("y-dy-callbacks");
- for (SCM i = list; gh_pair_p (i); i = ly_cdr (i))
- gh_call1 (ly_car (i), smob);
+ if (ly_car (s) == SCM_BOOL_F)
+ {
- // UGH. Y is not in staff position unit?
- // Ik dacht datwe daar juist van weg wilden?
-
- // Hmm, nu hebben we 3 dimensies, want inmiddels zijn we daar
- // weer terug, maar dan / 2
- // (staff-space iso staff-position)
-
- set_stem_lengths (me);
+ // one wonders if such genericity is necessary --hwn.
+ SCM callbacks = me->get_grob_property ("position-callbacks");
+ for (SCM i = callbacks; gh_pair_p (i); i = ly_cdr (i))
+ gh_call1 (ly_car (i), smob);
+ }
+ set_stem_lengths (me);
return SCM_UNSPECIFIED;
}
-
MAKE_SCHEME_CALLBACK (Beam, least_squares, 1);
SCM
Beam::least_squares (SCM smob)
{
- Grob *me = unsmob_grob (smob);
+ Grob *me = unsmob_grob (smob);
- if (visible_stem_count (me) <= 1)
- return SCM_UNSPECIFIED;
+ int count = visible_stem_count (me);
+ Interval pos (0, 0);
+
+ if (count <= 1)
+ {
+ me->set_grob_property ("positions", ly_interval2scm (pos));
+ return SCM_UNSPECIFIED;
+ }
- Real y = 0;
- Real dy = 0;
- /* Stem_info, and thus y,dy in this function are corrected for beam-dir */
- Real first_ideal = Stem::calc_stem_info (first_visible_stem (me)).idealy_f_;
- if (first_ideal == Stem::calc_stem_info (last_visible_stem (me)).idealy_f_)
+ Array<Real> x_posns ;
+ Link_array<Grob> stems=
+ Pointer_group_interface__extract_grobs (me, (Grob*)0, "stems");
+ Grob *commonx = common_refpoint_of_array (stems, me, X_AXIS);
+ Grob *commony = common_refpoint_of_array (stems, me, Y_AXIS);
+
+ Real my_y = me->relative_coordinate (commony, Y_AXIS);
+
+ Grob *fvs = first_visible_stem (me);
+ Grob *lvs = last_visible_stem (me);
+
+ Interval ideal (Stem::get_stem_info (fvs).ideal_y_
+ + fvs->relative_coordinate (commony, Y_AXIS) -my_y,
+ Stem::get_stem_info (lvs).ideal_y_
+ + lvs->relative_coordinate (commony, Y_AXIS) - my_y);
+
+ Real x0 = first_visible_stem (me)->relative_coordinate (commonx, X_AXIS);
+ for (int i=0; i < stems.size (); i++)
{
- y = first_ideal;
- dy = 0;
+ Grob* s = stems[i];
+
+ Real x = s->relative_coordinate (commonx, X_AXIS) - x0;
+ x_posns.push (x);
}
- else
+ Real dx = last_visible_stem (me)->relative_coordinate (commonx, X_AXIS) - x0;
+
+ Real y =0;
+ Real dydx = 0;
+ Real dy = 0;
+
+ if (!ideal.delta ())
{
- Array<Offset> ideals;
+ Interval chord (Stem::chord_start_y (first_visible_stem (me)),
+ Stem::chord_start_y (last_visible_stem (me)));
- // ugh -> use commonx
- Real x0 = first_visible_stem (me)->relative_coordinate (0, X_AXIS);
- Link_array<Item> stems=
- Pointer_group_interface__extract_elements (me, (Item*)0, "stems");
+ /* Simple beams (2 stems) on middle line should be allowed to be
+ slightly sloped.
+
+ However, if both stems reach middle line,
+ ideal[LEFT] == ideal[RIGHT] and ideal.delta () == 0.
+
+ For that case, we apply artificial slope */
+ if (!ideal[LEFT] && chord.delta () && count == 2)
+ {
+ /* FIXME. -> UP */
+ Direction d = (Direction) (sign (chord.delta ()) * UP);
+ pos[d] = gh_scm2double (me->get_grob_property ("thickness")) / 2;
+ pos[-d] = - pos[d];
+ }
+ else
+ {
+ pos = ideal;
+ }
+ y = pos[LEFT];
+ dy = pos[RIGHT]- y;
+ dydx = dy/dx;
+ }
+ else
+ {
+ Array<Offset> ideals;
for (int i=0; i < stems.size (); i++)
{
- Item* s = stems[i];
+ Grob* s = stems[i];
if (Stem::invisible_b (s))
continue;
- ideals.push (Offset (s->relative_coordinate (0, X_AXIS) - x0,
- Stem::calc_stem_info (s).idealy_f_));
+ ideals.push (Offset (x_posns[i],
+ Stem::get_stem_info (s).ideal_y_
+ + s->relative_coordinate (commony, Y_AXIS)
+ - my_y));
}
- Real dydx;
minimise_least_squares (&dydx, &y, ideals);
- Real dx = last_visible_stem (me)->relative_coordinate (0, X_AXIS) - x0;
dy = dydx * dx;
+ me->set_grob_property ("least-squares-dy", gh_double2scm (dy));
+ pos = Interval (y, (y+dy));
}
- /* Store true, not dir-corrected values */
- Direction dir = Directional_element_interface::get (me);
- me->set_grob_property ("y", gh_double2scm (y * dir));
- me->set_grob_property ("dy", gh_double2scm (dy * dir));
+ me->set_grob_property ("positions", ly_interval2scm (pos));
+
+ return SCM_UNSPECIFIED;
+}
+
+
+/*
+ We can't combine with previous function, since check concave and
+ slope damping comes first.
+ */
+MAKE_SCHEME_CALLBACK (Beam, shift_region_to_valid, 1);
+SCM
+Beam::shift_region_to_valid (SCM grob)
+{
+ Grob *me = unsmob_grob (grob);
+ /*
+ Code dup.
+ */
+ Array<Real> x_posns ;
+ Link_array<Grob> stems=
+ Pointer_group_interface__extract_grobs (me, (Grob*)0, "stems");
+ Grob *commonx = common_refpoint_of_array (stems, me, X_AXIS);
+ Grob *commony = common_refpoint_of_array (stems, me, Y_AXIS);
+
+ Grob *fvs = first_visible_stem (me);
+
+ if (!fvs)
+ return SCM_UNSPECIFIED;
+
+ Real x0 =fvs->relative_coordinate (commonx, X_AXIS);
+ for (int i=0; i < stems.size (); i++)
+ {
+ Grob* s = stems[i];
+
+ Real x = s->relative_coordinate (commonx, X_AXIS) - x0;
+ x_posns.push (x);
+ }
+
+ Grob *lvs = last_visible_stem (me);
+ if (!lvs)
+ return SCM_UNSPECIFIED;
+
+ Real dx = lvs->relative_coordinate (commonx, X_AXIS) - x0;
+
+ Interval pos = ly_scm2interval ( me->get_grob_property ("positions"));
+ Real dy = pos.delta();
+ Real y = pos[LEFT];
+ Real dydx =dy/dx;
+
+
+ /*
+ Shift the positions so that we have a chance of finding good
+ quants (i.e. no short stem failures.)
+ */
+ Interval feasible_left_point;
+ feasible_left_point.set_full ();
+ for (int i=0; i < stems.size (); i++)
+ {
+ Grob* s = stems[i];
+ if (Stem::invisible_b (s))
+ continue;
+
+ Direction d = Stem::get_direction (s);
+
+ Real left_y =
+ Stem::get_stem_info (s).shortest_y_
+ - dydx * x_posns [i];
+
+ /*
+ left_y is now relative to the stem S. We want relative to
+ ourselves, so translate:
+ */
+ left_y +=
+ + s->relative_coordinate (commony, Y_AXIS)
+ - me->relative_coordinate (commony, Y_AXIS);
+
+ Interval flp ;
+ flp.set_full ();
+ flp[-d] = left_y;
+
+ feasible_left_point.intersect (flp);
+ }
+
+ if (feasible_left_point.empty_b())
+ {
+ warning (_("Not sure that we can find a nice beam slope (no viable initial configuration found)."));
+ }
+ else if (!feasible_left_point.elem_b(y))
+ {
+ if (isinf (feasible_left_point[DOWN]))
+ y = feasible_left_point[UP] - REGION_SIZE;
+ else if (isinf (feasible_left_point[UP]))
+ y = feasible_left_point[DOWN]+ REGION_SIZE;
+ else
+ y = feasible_left_point.center ();
+ }
+ pos = Interval (y, (y+dy));
+ me->set_grob_property ("positions", ly_interval2scm (pos));
return SCM_UNSPECIFIED;
}
-MAKE_SCHEME_CALLBACK (Beam, cancel_suspect_slope, 1);
+
+MAKE_SCHEME_CALLBACK (Beam, check_concave, 1);
SCM
-Beam::cancel_suspect_slope (SCM smob)
+Beam::check_concave (SCM smob)
{
Grob *me = unsmob_grob (smob);
+
+ Link_array<Grob> stems =
+ Pointer_group_interface__extract_grobs (me, (Grob*) 0, "stems");
+
+ for (int i = 0; i < stems.size ();)
+ {
+ if (Stem::invisible_b (stems[i]))
+ stems.del (i);
+ else
+ i++;
+ }
- if (visible_stem_count (me) <= 1)
+ 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 concaveness1 = false;
+ SCM gap = me->get_grob_property ("concaveness-gap");
+ if (gh_number_p (gap)
+ && Stem::get_direction(stems.top ())
+ == Stem::get_direction(stems[0]))
+ {
+ 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 = (Stem::chord_start_y (stems[i]) - y0) - i * slope;
+ if (c > r1)
+ {
+ concaveness1 = 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.
+ */
- /* Stem_info, and thus y,dy in this function are corrected for beam-dir */
- Direction dir = Directional_element_interface::get (me);
- Real y = gh_scm2double (me->get_grob_property ("y")) * dir;
- Real dy = gh_scm2double (me->get_grob_property ("dy")) * dir;
-
- /* steep slope running against lengthened stem is suspect */
- Real first_ideal = Stem::calc_stem_info (first_visible_stem (me)).idealy_f_;
- Real last_ideal = Stem::calc_stem_info (last_visible_stem (me)).idealy_f_;
- Real lengthened = gh_scm2double (me->get_grob_property ("outer-stem-length-limit"));
- Real steep = gh_scm2double (me->get_grob_property ("slope-limit"));
+ Real concaveness2 = 0;
+ SCM thresh = me->get_grob_property ("concaveness-threshold");
+ Real r2 = infinity_f;
+ if (!concaveness1 && gh_number_p (thresh)
+ && Stem::get_direction(stems.top ())
+ == Stem::get_direction(stems[0]))
+ {
+ r2 = gh_scm2double (thresh);
- // ugh -> use commonx
- Real dx = last_visible_stem (me)->relative_coordinate (0, X_AXIS) - first_visible_stem (me)->relative_coordinate (0, X_AXIS);
- Real dydx = dy && dx ? dy/dx : 0;
+ Direction dir = Stem::get_direction(stems.top ());
+ Real concave = 0;
+ Interval iv (Stem::chord_start_y (stems[0]),
+ Stem::chord_start_y (stems.top ()));
+
+ if (iv[MAX] < iv[MIN])
+ iv.swap ();
+
+ for (int i = 1; i < stems.size () - 1; i++)
+ {
+ Real f = Stem::chord_start_y (stems[i]);
+ concave += ((f - iv[MAX] ) >? 0) +
+ ((f - iv[MIN] ) <? 0);
+ }
+ concave *= dir;
+ concaveness2 = concave / (stems.size () - 2);
+
+ /* ugh: this is the a kludge to get
+ input/regression/beam-concave.ly to behave as
+ baerenreiter. */
+
+ /*
+ huh? we're dividing twice (which is not scalable) meaning that
+ the longer the beam, the more unlikely it will be
+ concave. Maybe you would even expect the other way around??
- if (( (y - first_ideal > lengthened) && (dydx > steep))
- || ((y + dy - last_ideal > lengthened) && (dydx < -steep)))
+ --hwn.
+
+ */
+ concaveness2 /= (stems.size () - 2);
+ }
+
+ /* TODO: some sort of damping iso -> plain horizontal */
+ if (concaveness1 || concaveness2 > r2)
{
- Real adjusted_y = y + dy / 2;
- /* Store true, not dir-corrected values */
- me->set_grob_property ("y", gh_double2scm (adjusted_y * dir));
- me->set_grob_property ("dy", gh_double2scm (0));
+ Interval pos = ly_scm2interval (me->get_grob_property ("positions"));
+ Real r = pos.linear_combination (0);
+ me->set_grob_property ("positions", ly_interval2scm (Interval (r, r)));
+ me->set_grob_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]
-*/
+/* This neat trick is by Werner Lemberg,
+ damped = tanh (slope)
+ corresponds with some tables in [Wanske] CHECKME */
MAKE_SCHEME_CALLBACK (Beam, slope_damping, 1);
SCM
Beam::slope_damping (SCM smob)
if (damping)
{
- /* y,dy in this function are corrected for beam-dir */
- Direction dir = Directional_element_interface::get (me);
- Real y = gh_scm2double (me->get_grob_property ("y")) * dir;
- Real dy = gh_scm2double (me->get_grob_property ("dy")) * dir;
-
- // ugh -> use commonx
- Real dx = last_visible_stem (me)->relative_coordinate (0, X_AXIS)
- - first_visible_stem (me)->relative_coordinate (0, X_AXIS);
- Real dydx = dy && dx ? dy/dx : 0;
- dydx = 0.6 * tanh (dydx) / damping;
+ Interval pos = ly_scm2interval (me->get_grob_property ("positions"));
+ Real dy = pos.delta ();
- Real damped_dy = dydx * dx;
- Real adjusted_y = y + (dy - damped_dy) / 2;
- /* Store true, not dir-corrected values */
- me->set_grob_property ("y", gh_double2scm (adjusted_y * dir));
- me->set_grob_property ("dy", gh_double2scm (damped_dy * dir));
- }
- return SCM_UNSPECIFIED;
-}
+ Grob *fvs = first_visible_stem (me);
+ Grob *lvs = last_visible_stem (me);
-/*
- Quantise dy (height) of beam.
- Generalisation of [Ross].
- */
-MAKE_SCHEME_CALLBACK (Beam, quantise_dy, 1);
-SCM
-Beam::quantise_dy (SCM smob)
-{
- Grob *me = unsmob_grob (smob);
+ Grob *commonx = fvs->common_refpoint (lvs, X_AXIS);
- if (visible_stem_count (me) <= 1)
- return SCM_UNSPECIFIED;
- Array<Real> a;
- SCM proc = me->get_grob_property ("height-quants");
- SCM quants = gh_call2 (proc, me->self_scm (),
- gh_double2scm (me->paper_l ()->get_var ("stafflinethickness")
- / 1.0));
-
- for (SCM s = quants; gh_pair_p (s); s = ly_cdr (s))
- a.push (gh_scm2double (ly_car (s)));
-
- if (a.size () > 1)
- {
- /* y,dy in this function are corrected for beam-dir */
- Direction dir = Directional_element_interface::get (me);
- Real y = gh_scm2double (me->get_grob_property ("y")) * dir;
- Real dy = gh_scm2double (me->get_grob_property ("dy")) * dir;
+ 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 staff_space = Staff_symbol_referencer::staff_space (me);
-
- Interval iv = quantise_iv (a, abs (dy)/staff_space) * staff_space;
- Real q = (abs (dy) - iv[SMALLER] <= iv[BIGGER] - abs (dy))
- ? iv[SMALLER]
- : iv[BIGGER];
+ Real damped_dy = dydx * dx;
+ pos[LEFT] += (dy - damped_dy) / 2;
+ pos[RIGHT] -= (dy - damped_dy) / 2;
- Real quantised_dy = q * sign (dy);
- Real adjusted_y = y + (dy - quantised_dy) / 2;
- /* Store true, not dir-corrected values */
- me->set_grob_property ("y", gh_double2scm (adjusted_y * dir));
- me->set_grob_property ("dy", gh_double2scm (quantised_dy * dir));
- }
- return SCM_UNSPECIFIED;
-}
-
-/* It's tricky to have the user override y,dy directly, so we use this
- translation func. Also, if our staff_space != 1 (smaller staff, eg),
- user will expect staff-position to be discrete values. */
-MAKE_SCHEME_CALLBACK (Beam, user_override, 1);
-SCM
-Beam::user_override (SCM smob)
-{
- Grob *me = unsmob_grob (smob);
- Real staff_space = Staff_symbol_referencer::staff_space (me);
-
- SCM s = me->get_grob_property ("staff-position");
- if (gh_number_p (s))
- {
- Real y = gh_scm2double (s) * staff_space * 0.5;
- me->set_grob_property ("y", gh_double2scm (y));
+ me->set_grob_property ("positions", ly_interval2scm (pos));
}
-
- /* Name suggestions? Tilt, slope, vertical-* ? */
- s = me->get_grob_property ("height");
- if (gh_number_p (s))
- {
- Real dy = gh_scm2double (s) * staff_space * 0.5;
- me->set_grob_property ("dy", gh_double2scm (dy));
- }
-
return SCM_UNSPECIFIED;
}
/*
- Ugh, this must be last, after user_override
- Assumes directionised y/dy.
+ Report slice containing the numbers that are both in (car BEAMING)
+ and (cdr BEAMING)
*/
-MAKE_SCHEME_CALLBACK (Beam, do_quantise_y, 1);
-SCM
-Beam::do_quantise_y (SCM smob)
+Slice
+where_are_the_whole_beams(SCM beaming)
{
- Grob *me = unsmob_grob (smob);
-
- /*
- If the user set y-position, we shouldn't do quanting.
- */
- if (gh_number_p (me->get_grob_property ("y-position-hs")))
- return SCM_UNSPECIFIED;
-
- Real y = gh_scm2double (me->get_grob_property ("y"));
- Real dy = gh_scm2double (me->get_grob_property ("dy"));
-
- /* we can modify y, so we should quantise y */
- Real half_space = Staff_symbol_referencer::staff_space (me) / 2;
- Real y_shift = check_stem_length_f (me, y, dy);
- y += y_shift;
- y = quantise_y_f (me, y, dy, 0);
-
- /*
- Hmm, this is a bit keyhole operation: we're passing `this' as a
- parameter, and member vars as SCM properties. We should decide on
- SCM/C/C++ boundary */
- me->set_grob_property ("y", gh_double2scm (y));
- set_stem_lengths (me);
- y = gh_scm2double (me->get_grob_property ("y"));
+ Slice l;
- y_shift = check_stem_length_f (me, y, dy);
-
- if (y_shift > half_space / 4)
+ for( SCM s = gh_car (beaming); gh_pair_p (s) ; s = gh_cdr (s))
{
- y += y_shift;
-
- /*
- for significantly lengthened or shortened stems,
- request quanting the other way.
- */
- int quant_dir = 0;
- if (abs (y_shift) > half_space / 2)
- quant_dir = sign (y_shift) * Directional_element_interface::get (me);
- y = quantise_y_f (me, y, dy, quant_dir);
+ if (scm_memq (gh_car (s), gh_cdr (beaming)) != SCM_BOOL_F)
+
+ l.add_point (gh_scm2int (gh_car (s)));
}
-
- me->set_grob_property ("y", gh_double2scm (y));
- // me->set_grob_property ("dy", gh_double2scm (dy));
- return SCM_UNSPECIFIED;
-}
-
-
-Real
-Beam::calc_stem_y_f (Grob*me,Item* s, Real y, Real dy)
-{
- 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) ;
- // ugh -> use commonx
- Real x0 = first_visible_stem (me)->relative_coordinate (0, X_AXIS);
- Real dx = last_visible_stem (me)->relative_coordinate (0, X_AXIS) - x0;
- Real stem_y = (dy && dx ? (s->relative_coordinate (0, X_AXIS) - x0) / dx * dy : 0) + y;
-
- /* knee */
- Direction dir = Directional_element_interface::get (me);
- Direction sdir = Directional_element_interface::get (s);
-
- /* knee */
- if (dir!= sdir)
- {
- stem_y -= dir
- * (thick / 2 + (beam_multiplicity - 1) * interbeam_f);
-
-
-
- // 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;
- }
-
- return stem_y;
+ return l;
}
+/* Return the Y position of the stem-end, given the Y-left, Y-right
+ in POS for stem S. This Y position is relative to S. */
Real
-Beam::check_stem_length_f (Grob*me,Real y, Real dy)
+Beam::calc_stem_y (Grob *me, Grob* s, Grob ** common,
+ Real xl, Real xr,
+ Interval pos, bool french)
{
- Real shorten = 0;
- Real lengthen = 0;
- Direction dir = Directional_element_interface::get (me);
-
- Link_array<Item> stems=
- Pointer_group_interface__extract_elements (me, (Item*)0, "stems");
+ Real beam_translation = get_beam_translation (me);
- for (int i=0; i < stems.size (); i++)
+
+ Real r = s->relative_coordinate (common[X_AXIS], X_AXIS) - xl;
+ Real dy = pos.delta ();
+ Real dx = xr - xl;
+ Real stem_y_beam0 = (dy && dx
+ ? r / dx
+ * dy
+ : 0) + pos[LEFT];
+
+ Direction my_dir = Directional_element_interface::get (s);
+ SCM beaming = s->get_grob_property ("beaming");
+
+ Real stem_y = stem_y_beam0;
+ if (french)
{
- Item* s = stems[i];
- if (Stem::invisible_b (s))
- continue;
-
- Real stem_y = calc_stem_y_f (me, s, y, dy);
-
- stem_y *= dir;
- Stem_info info = Stem::calc_stem_info (s);
-
- // if (0 > info.maxy_f_ - stem_y)
- shorten = shorten <? info.maxy_f_ - stem_y;
- // if (0 < info.miny_f_ - stem_y)
- lengthen = lengthen >? info.miny_f_ - stem_y;
+ Slice bm = where_are_the_whole_beams (beaming);
+ if (!bm.empty_b())
+ stem_y += beam_translation * bm[-my_dir];
}
-
- if (lengthen && shorten)
- warning (_ ("weird beam vertical offset"));
-
- /* when all stems are too short, normal stems win */
- return dir * ((shorten) ? shorten : lengthen);
+ else
+ {
+ Slice bm = Stem::beam_multiplicity(s);
+ if (!bm.empty_b())
+ stem_y +=bm[my_dir] * beam_translation;
+ }
+
+ Real id = me->relative_coordinate (common[Y_AXIS], Y_AXIS)
+ - s->relative_coordinate (common[Y_AXIS], Y_AXIS);
+
+ return stem_y + id;
}
/*
void
Beam::set_stem_lengths (Grob *me)
{
- if (visible_stem_count (me) <= 1)
+ Link_array<Grob> stems=
+ Pointer_group_interface__extract_grobs (me, (Grob*)0, "stems");
+
+ if (stems.size () <= 1)
return;
- Real y = gh_scm2double (me->get_grob_property ("y"));
- Real dy = gh_scm2double (me->get_grob_property ("dy"));
-
- Real half_space = Staff_symbol_referencer::staff_space (me)/2;
- Link_array<Item> stems=
- Pointer_group_interface__extract_elements (me, (Item*)0, "stems");
+ Grob *common[2];
+ for (int a = 2; a--;)
+ common[a] = common_refpoint_of_array (stems, me, Axis(a));
+
+ Interval pos = ly_scm2interval (me->get_grob_property ("positions"));
+ Real staff_space = Staff_symbol_referencer::staff_space (me);
- Grob *common = me->common_refpoint (stems[0], Y_AXIS);
- for (int i=1; i < stems.size (); i++)
- if (!Stem::invisible_b (stems[i]))
- common = common->common_refpoint (stems[i], Y_AXIS);
+ bool french = to_boolean (me->get_grob_property ("french-beaming"));
+
+ bool gap = false;
+ Real thick =0.0;
+ if (gh_number_p (me->get_grob_property ("gap"))
+ &&gh_scm2double (me->get_grob_property ("gap")))
+ {
+ gap = true;
+ thick = get_thickness(me);
+ }
+
+ // ugh -> use commonx
+ Grob * fvs = first_visible_stem (me);
+ Grob *lvs = last_visible_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;
+
for (int i=0; i < stems.size (); i++)
{
- Item* s = stems[i];
+ Grob* s = stems[i];
if (Stem::invisible_b (s))
continue;
- Real stem_y = calc_stem_y_f (me, s, y, dy);
+ Real stem_y = calc_stem_y (me, s, common,
+ xl, xr,
+ pos, french && i > 0&& (i < stems.size () -1));
- // doesn't play well with dvips
- if (scm_definedp (ly_symbol2scm ("ps-testing"), SCM_UNDEFINED)
- == SCM_BOOL_T)
- if (Stem::get_direction (s) == Directional_element_interface::get (me))
- stem_y += Stem::get_direction (s)
- * gh_scm2double (me->get_grob_property ("thickness")) / 2;
+ /*
+ Make the stems go up to the end of the beam. This doesn't matter
+ for normal beams, but for tremolo beams it looks silly otherwise.
+ */
+ if (gap)
+ stem_y += thick * 0.5 * Directional_element_interface::get(s);
- /* caution: stem measures in staff-positions */
- Real id = me->relative_coordinate (common, Y_AXIS)
- - stems[i]->relative_coordinate (common, Y_AXIS);
- Stem::set_stemend (s, (stem_y + id) / half_space);
+ Stem::set_stemend (s, 2* stem_y / staff_space);
}
}
-/*
- Prevent interference from stafflines and beams.
-
- We only need to quantise the (left) y of the beam,
- since dy is quantised too.
- if extend_b then stems must *not* get shorter
- */
-Real
-Beam::quantise_y_f (Grob*me,Real y, Real dy, int quant_dir)
-{
- int multiplicity = get_multiplicity (me);
-
- Real staff_space = Staff_symbol_referencer::staff_space (me);
- Real thick = me->paper_l ()->get_var ("stafflinethickness");
-
-
- SCM proc = me->get_grob_property ("vertical-position-quant-function");
- SCM quants = scm_apply (proc,
- me->self_scm (),
- scm_list_n (gh_int2scm (multiplicity),
- gh_double2scm (dy/staff_space),
- gh_double2scm (thick/staff_space),
- SCM_EOL, SCM_UNDEFINED));
-
- Array<Real> a;
-
- for (; gh_pair_p (quants); quants = ly_cdr (quants))
- a.push (gh_scm2double (ly_car (quants)));
-
- if (a.size () <= 1)
- return y;
-
- Real up_y = Directional_element_interface::get (me) * y;
- Interval iv = quantise_iv (a, up_y/staff_space) * staff_space;
-
- Real q = up_y - iv[SMALLER] <= iv[BIGGER] - up_y
- ? iv[SMALLER] : iv[BIGGER];
- if (quant_dir)
- q = iv[ (Direction)quant_dir];
-
- return q * Directional_element_interface::get (me);
-}
-
void
-Beam::set_beaming (Grob*me,Beaming_info_list *beaming)
+Beam::set_beaming (Grob *me, Beaming_info_list *beaming)
{
Link_array<Grob> stems=
- Pointer_group_interface__extract_elements (me, (Grob*)0, "stems");
+ Pointer_group_interface__extract_grobs (me, (Grob *)0, "stems");
Direction d = LEFT;
for (int i=0; i < stems.size (); i++)
{
- do
- {
- /* Don't overwrite user override (?) */
- if (Stem::beam_count (stems[i], d) == 0
- /* Don't set beaming for outside of outer stems */
- && ! (d == LEFT && i == 0)
- && ! (d == RIGHT && i == stems.size () -1))
- {
- int b = beaming->infos_.elem (i).beams_i_drul_[d];
- Stem::set_beaming (stems[i], b, d);
- }
- }
- while (flip (&d) != LEFT);
- }
-}
-
-
-
-/*
- beams to go with one stem.
-
- FIXME: clean me up.
- */
-Molecule
-Beam::stem_beams (Grob*me,Item *here, Item *next, Item *prev,
- Real /* dy */ , Real dydx
- )
-{
- // ugh -> use commonx
- if ((next && ! (next->relative_coordinate (0, X_AXIS) > here->relative_coordinate (0, X_AXIS))) ||
- (prev && ! (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;
-
-#if 0
- // ugh -> use commonx
- Real dx = visible_stem_count (me) ?
- last_visible_stem (me)->relative_coordinate (0, X_AXIS) - first_visible_stem (me)->relative_coordinate (0, X_AXIS)
- : 0.0;
-#endif
-
- Molecule leftbeams;
- Molecule rightbeams;
-
- Real nw_f;
- if (!Stem::first_head (here))
- nw_f = 0;
- else {
- int t = Stem::type_i (here);
-
- SCM proc = me->get_grob_property ("flag-width-function");
- SCM result = gh_call1 (proc, gh_int2scm (t));
- nw_f = gh_scm2double (result);
- }
-
-
- Direction dir = Directional_element_interface::get (me);
-
- /* [Tremolo] beams on whole notes may not have direction set? */
- if (dir == CENTER)
- dir = Directional_element_interface::get (here);
-
-
- /* half beams extending to the left. */
- if (prev)
- {
- int lhalfs= lhalfs = Stem::beam_count (here,LEFT) - Stem::beam_count (prev,RIGHT);
- int lwholebeams= Stem::beam_count (here,LEFT) <? Stem::beam_count (prev,RIGHT) ;
/*
- Half beam should be one note-width,
- but let's make sure two half-beams never touch
+ Don't overwrite user settings.
*/
-
- // FIXME: TODO (check) stem width / sloped beams
- Real w = here->relative_coordinate (0, X_AXIS)
- - prev->relative_coordinate (0, X_AXIS);
- Real stem_w = gh_scm2double (prev->get_grob_property ("thickness"))
- // URG
- * me->paper_l ()->get_var ("stafflinethickness");
-
- w = w/2 <? nw_f;
- Molecule a;
- if (lhalfs) // generates warnings if not
- a = Lookup::beam (dydx, w + stem_w, thick);
- a.translate (Offset (-w, -w * dydx));
- a.translate_axis (-stem_w/2, X_AXIS);
- for (int j = 0; j < lhalfs; j++)
+
+ do
{
- Molecule b (a);
- b.translate_axis (-dir * bdy * (lwholebeams+j), Y_AXIS);
- leftbeams.add_molecule (b);
- }
- }
-
- if (next)
- {
- int rhalfs = Stem::beam_count (here,RIGHT)
- - Stem::beam_count (next,LEFT);
- int rwholebeams= Stem::beam_count (here,RIGHT)
- <? Stem::beam_count (next,LEFT) ;
-
- Real w = next->relative_coordinate (0, X_AXIS)
- - here->relative_coordinate (0, X_AXIS);
+ /* Don't set beaming for outside of outer stems */
+ if ((d == LEFT && i == 0)
+ ||(d == RIGHT && i == stems.size () -1))
+ continue;
- Real stem_w = gh_scm2double (next->get_grob_property ("thickness"))
- // URG
- * me->paper_l ()->get_var ("stafflinethickness");
- Molecule a = Lookup::beam (dydx, w + stem_w, thick);
- a.translate_axis (- stem_w/2, X_AXIS);
- int j = 0;
- Real gap_f = 0;
-
- SCM gap = me->get_grob_property ("gap");
- if (gh_number_p (gap))
- {
- int gap_i = gh_scm2int ((gap));
- int nogap = rwholebeams - gap_i;
-
- for (; j < nogap; j++)
+ SCM beaming_prop = stems[i]->get_grob_property ("beaming");
+ if (beaming_prop == SCM_EOL ||
+ index_get_cell (beaming_prop, d) == SCM_EOL)
{
- Molecule b (a);
- b.translate_axis (-dir * bdy * j, Y_AXIS);
- rightbeams.add_molecule (b);
+ int b = beaming->infos_.elem (i).beams_i_drul_[d];
+ Stem::set_beaming (stems[i], b, d);
}
- if (Stem::invisible_b (here))
- gap_f = nw_f;
- else
- gap_f = nw_f / 2;
- w -= 2 * gap_f;
- a = Lookup::beam (dydx, w + stem_w, thick);
- }
-
- for (; j < rwholebeams; j++)
- {
- Molecule b (a);
- Real tx = 0;
- if (Stem::invisible_b (here))
- // ugh, see chord-tremolo.ly
- tx = (-dir + 1) / 2 * nw_f * 1.5 + gap_f/4;
- else
- tx = gap_f;
- b.translate (Offset (tx, -dir * bdy * j));
- rightbeams.add_molecule (b);
}
-
- w = w/2 <? nw_f;
- if (rhalfs)
- a = Lookup::beam (dydx, w, thick);
-
- for (; j < rwholebeams + rhalfs; j++)
- {
- Molecule b (a);
- b.translate_axis (- dir * bdy * j, Y_AXIS);
- rightbeams.add_molecule (b);
- }
-
- }
- leftbeams.add_molecule (rightbeams);
-
- /*
- Does beam quanting think of the asymetry of beams?
- Refpoint is on bottom of symbol. (FIXTHAT) --hwn.
- */
- return leftbeams;
-}
-
-MAKE_SCHEME_CALLBACK (Beam,brew_molecule,1);
-SCM
-Beam::brew_molecule (SCM smob)
-{
- Grob * me =unsmob_grob (smob);
-
- Molecule mol;
- if (!gh_pair_p (me->get_grob_property ("stems")))
- return SCM_EOL;
- Real x0,dx;
- Link_array<Item>stems =
- Pointer_group_interface__extract_elements (me, (Item*) 0, "stems");
- if (visible_stem_count (me))
- {
- // ugh -> use commonx
- x0 = first_visible_stem (me)->relative_coordinate (0, X_AXIS);
- dx = last_visible_stem (me)->relative_coordinate (0, X_AXIS) - x0;
- }
- else
- {
- x0 = stems[0]->relative_coordinate (0, X_AXIS);
- dx = stems.top ()->relative_coordinate (0, X_AXIS) - x0;
- }
-
-
-
- /*
- TODO: the naming of the grob properties sucks.
- */
- SCM dy_s = me->get_grob_property ("dy");
- SCM y_s = me->get_grob_property ("y");
-
-
- Real dy = gh_number_p (dy_s) ? gh_scm2double (dy_s) : 0.0;
- Real dydx = dy && dx ? dy/dx : 0;
- Real y = gh_number_p (y_s) ? gh_scm2double (y_s) : 0.0;
-
-
- for (int j=0; j <stems.size (); j++)
- {
- Item *i = stems[j];
- Item * prev = (j > 0)? stems[j-1] : 0;
- Item * next = (j < stems.size ()-1) ? stems[j+1] :0;
-
- Molecule sb = stem_beams (me, i, next, prev, dy, dydx);
- Real x = i->relative_coordinate (0, X_AXIS)-x0;
- sb.translate (Offset (x, x * dydx + y));
- mol.add_molecule (sb);
+ while (flip (&d) != LEFT);
}
- mol.translate_axis (x0
- - dynamic_cast<Spanner*> (me)->get_bound (LEFT)->relative_coordinate (0, X_AXIS), X_AXIS);
-
- return mol.smobbed_copy ();
}
int
-Beam::forced_stem_count (Grob*me)
+Beam::forced_stem_count (Grob *me)
{
- Link_array<Item>stems =
- Pointer_group_interface__extract_elements (me, (Item*) 0, "stems");
+ Link_array<Grob>stems =
+ Pointer_group_interface__extract_grobs (me, (Grob*) 0, "stems");
int f = 0;
for (int i=0; i < stems.size (); i++)
{
- Item *s = stems[i];
+ Grob *s = stems[i];
if (Stem::invisible_b (s))
continue;
- if (( (int)Stem::chord_start_f (s))
+ /* I can imagine counting those boundaries as a half forced stem,
+ but let's count them full for now. */
+ if (abs (Stem::chord_start_y (s)) > 0.1
&& (Stem::get_direction (s) != Stem::get_default_dir (s)))
f++;
}
-/* TODO:
- use filter and standard list functions.
- */
int
-Beam::visible_stem_count (Grob*me)
+Beam::visible_stem_count (Grob *me)
{
- Link_array<Item>stems =
- Pointer_group_interface__extract_elements (me, (Item*) 0, "stems");
+ Link_array<Grob>stems =
+ Pointer_group_interface__extract_grobs (me, (Grob*) 0, "stems");
int c = 0;
for (int i = stems.size (); i--;)
{
return c;
}
-Item*
-Beam::first_visible_stem (Grob*me)
+Grob*
+Beam::first_visible_stem (Grob *me)
{
- Link_array<Item>stems =
- Pointer_group_interface__extract_elements (me, (Item*) 0, "stems");
+ Link_array<Grob>stems =
+ Pointer_group_interface__extract_grobs (me, (Grob*) 0, "stems");
for (int i = 0; i < stems.size (); i++)
{
return 0;
}
-Item*
-Beam::last_visible_stem (Grob*me)
+Grob*
+Beam::last_visible_stem (Grob *me)
{
- Link_array<Item>stems =
- Pointer_group_interface__extract_elements (me, (Item*) 0, "stems");
+ Link_array<Grob>stems =
+ Pointer_group_interface__extract_grobs (me, (Grob*) 0, "stems");
for (int i = stems.size (); i--;)
{
if (!Stem::invisible_b (stems[i]))
/*
[TODO]
+
handle rest under beam (do_post: beams are calculated now)
what about combination of collisions and rest under beam.
rest -> stem -> beam -> interpolate_y_position ()
*/
-MAKE_SCHEME_CALLBACK (Beam,rest_collision_callback,2);
+MAKE_SCHEME_CALLBACK (Beam, rest_collision_callback, 2);
SCM
Beam::rest_collision_callback (SCM element_smob, SCM axis)
{
assert (a == Y_AXIS);
- Grob * st = unsmob_grob (rest->get_grob_property ("stem"));
- Grob * stem = st;
+ Grob *st = unsmob_grob (rest->get_grob_property ("stem"));
+ Grob *stem = st;
if (!stem)
return gh_double2scm (0.0);
- Grob * beam = unsmob_grob (stem->get_grob_property ("beam"));
- if (!beam || !Beam::has_interface (beam) || !Beam::visible_stem_count (beam))
+ Grob *beam = unsmob_grob (stem->get_grob_property ("beam"));
+ if (!beam
+ || !Beam::has_interface (beam)
+ || !Beam::visible_stem_count (beam))
return gh_double2scm (0.0);
// make callback for rest from this.
- Real beam_dy = 0;
- Real beam_y = 0;
+ // todo: make sure this calced already.
+ // Interval pos = ly_scm2interval (beam->get_grob_property ("positions"));
+ Interval pos (0, 0);
+ SCM s = beam->get_grob_property ("positions");
+ if (gh_pair_p (s) && gh_number_p (ly_car (s)))
+ pos = ly_scm2interval (s);
- // todo: make sure this calced already.
- SCM s = beam->get_grob_property ("dy");
- if (gh_number_p (s))
- beam_dy = gh_scm2double (s);
-
- s = beam->get_grob_property ("y");
- if (gh_number_p (s))
- beam_y = gh_scm2double (s);
-
+ Real dy = pos.delta ();
// 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 = beam_dy && dx ? beam_dy/dx : 0;
-
+ Real dydx = dy && dx ? dy/dx : 0;
+
Direction d = Stem::get_direction (stem);
- Real beamy = (stem->relative_coordinate (0, X_AXIS) - x0) * dydx + beam_y;
+ 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??
+ Real rest_dim = rest->extent (rest, Y_AXIS)[d]*2.0 / staff_space; // refp??
Real minimum_dist
= gh_scm2double (rest->get_grob_property ("minimum-beam-collision-distance"));
return gh_double2scm (-d * discrete_dist);
}
-
bool
-Beam::has_interface (Grob*me)
+Beam::knee_b (Grob* me)
+{
+ SCM k = me->get_grob_property ("knee");
+ if (gh_boolean_p (k))
+ return gh_scm2bool (k);
+
+ bool knee = false;
+ int d = 0;
+ for (SCM s = me->get_grob_property ("stems"); gh_pair_p (s); s = ly_cdr (s))
+ {
+ Direction dir = Directional_element_interface::get
+ (unsmob_grob (ly_car (s)));
+ if (d && d != dir)
+ {
+ knee = true;
+ break;
+ }
+ d = dir;
+ }
+
+ me->set_grob_property ("knee", gh_bool2scm (knee));
+
+ return knee;
+}
+
+int
+Beam::get_direction_beam_count (Grob *me, Direction d )
{
- return me->has_interface (ly_symbol2scm ("beam-interface"));
+ Link_array<Grob>stems =
+ Pointer_group_interface__extract_grobs (me, (Grob*) 0, "stems");
+ int bc = 0;
+
+ for (int i = stems.size (); i--;)
+ {
+ /*
+ Should we take invisible stems into account?
+ */
+ if (Stem::get_direction (stems[i]) == d)
+ bc = bc >? (Stem::beam_multiplicity (stems[i]).length () + 1);
+ }
+
+ return bc;
}
+
+ADD_INTERFACE (Beam, "beam-interface",
+ "A beam.
+
+#'thickness= weight of beams, in staffspace
+
+
+We take the least squares line through the ideal-length stems, and
+then damp that using
+
+ damped = tanh (slope)
+
+this gives an unquantized left and right position for the beam end.
+Then we take all combinations of quantings near these left and right
+positions, and give them a score (according to how close they are to
+the ideal slope, how close the result is to the ideal stems, etc.). We
+take the best scoring combination.
+
+",
+ "knee french-beaming position-callbacks concaveness-gap concaveness-threshold dir-function quant-score auto-knee-gap gap chord-tremolo beamed-stem-shorten shorten least-squares-dy damping flag-width-function neutral-direction positions space-function thickness");
+
+